var bibbase_data = {"data":"<img src=\"//bibbase.org/img/ajax-loader.gif\" id=\"spinner\"\n  style=\"display: none;\" alt=\"Loading..\" />\n\n<div id=\"bibbase\">\n\n  <script type=\"text/javascript\">\n    var bibbase = {\n      params: {\"jsonp\":\"1\",\"host\":\"bibbase.org\",\"ssl\":false},\n      data: [{\"title\":\"Dephasing-covariant operations enable asymptotic reversibility of quantum resources\",\"type\":\"article\",\"year\":\"2018\",\"volume\":\"97\",\"id\":\"151c3e2c-da77-395f-ae97-e6ad45abcd64\",\"created\":\"2020-08-20T19:55:39.601Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.601Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2018 American Physical Society. We study the power of dephasing-covariant operations in the resource theories of coherence and entanglement. These are quantum operations whose actions commute with a projective measurement. In the resource theory of coherence, we find that any two states are asymptotically interconvertible under dephasing-covariant operations. This provides a rare example of a resource theory in which asymptotic reversibility can be attained without needing the maximal set of resource nongenerating operations. When extended to the resource theory of entanglement, the resultant operations share similarities with local operations and classical communication, such as prohibiting the increase of all Rényi α-entropies of entanglement under pure-state transformations. However, we show these operations are still strong enough to enable asymptotic reversibility between any two maximally correlated mixed states, even in the multipartite setting.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E.\",\"doi\":\"10.1103/PhysRevA.97.050301\",\"journal\":\"Physical Review A\",\"number\":\"5\",\"bibtex\":\"@article{\\n title = {Dephasing-covariant operations enable asymptotic reversibility of quantum resources},\\n type = {article},\\n year = {2018},\\n volume = {97},\\n id = {151c3e2c-da77-395f-ae97-e6ad45abcd64},\\n created = {2020-08-20T19:55:39.601Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.601Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2018 American Physical Society. We study the power of dephasing-covariant operations in the resource theories of coherence and entanglement. These are quantum operations whose actions commute with a projective measurement. In the resource theory of coherence, we find that any two states are asymptotically interconvertible under dephasing-covariant operations. This provides a rare example of a resource theory in which asymptotic reversibility can be attained without needing the maximal set of resource nongenerating operations. When extended to the resource theory of entanglement, the resultant operations share similarities with local operations and classical communication, such as prohibiting the increase of all Rényi α-entropies of entanglement under pure-state transformations. However, we show these operations are still strong enough to enable asymptotic reversibility between any two maximally correlated mixed states, even in the multipartite setting.},\\n bibtype = {article},\\n author = {Chitambar, E.},\\n doi = {10.1103/PhysRevA.97.050301},\\n journal = {Physical Review A},\\n number = {5}\\n}\",\"author_short\":[\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-dephasingcovariantoperationsenableasymptoticreversibilityofquantumresources-2018\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":2,\"html\":\"\"},{\"title\":\"Quantum correlations in high-dimensional states of high symmetry\",\"type\":\"article\",\"year\":\"2012\",\"volume\":\"86\",\"id\":\"baa02e1e-43b2-3dd1-a385-61bfb09db026\",\"created\":\"2020-08-20T19:55:39.602Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.602Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"In this article, we investigate how quantum correlations behave for the so-called Werner and pseudopure families of states. The latter refers to states formed by mixing any pure state with the totally mixed state. We derive closed expressions for the quantum discord and the relative entropy of quantumness for these families of states. For Werner states, the classical correlations are seen to vanish in high dimensions while the amount of quantum correlations remains bounded. For pseudopure states, nearly the opposite effect is observed, with both the quantum and classical correlations growing without bound as the dimension increases and only as the system becomes more entangled. In light of our calculations, we discuss how Werner states could play a role as a quantum one-time pad in cryptographic tasks and, along with isotropic states, could function as a quantum memory device designed to maximize the uncertainty tradeoff between noncommuting measurements on the individual subsystems. © 2012 American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E.\",\"doi\":\"10.1103/PhysRevA.86.032110\",\"journal\":\"Physical Review A - Atomic, Molecular, and Optical Physics\",\"number\":\"3\",\"bibtex\":\"@article{\\n title = {Quantum correlations in high-dimensional states of high symmetry},\\n type = {article},\\n year = {2012},\\n volume = {86},\\n id = {baa02e1e-43b2-3dd1-a385-61bfb09db026},\\n created = {2020-08-20T19:55:39.602Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.602Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {In this article, we investigate how quantum correlations behave for the so-called Werner and pseudopure families of states. The latter refers to states formed by mixing any pure state with the totally mixed state. We derive closed expressions for the quantum discord and the relative entropy of quantumness for these families of states. For Werner states, the classical correlations are seen to vanish in high dimensions while the amount of quantum correlations remains bounded. For pseudopure states, nearly the opposite effect is observed, with both the quantum and classical correlations growing without bound as the dimension increases and only as the system becomes more entangled. In light of our calculations, we discuss how Werner states could play a role as a quantum one-time pad in cryptographic tasks and, along with isotropic states, could function as a quantum memory device designed to maximize the uncertainty tradeoff between noncommuting measurements on the individual subsystems. © 2012 American Physical Society.},\\n bibtype = {article},\\n author = {Chitambar, E.},\\n doi = {10.1103/PhysRevA.86.032110},\\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\\n number = {3}\\n}\",\"author_short\":[\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-quantumcorrelationsinhighdimensionalstatesofhighsymmetry-2012\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Local quantum transformations requiring infinite rounds of classical communication\",\"type\":\"article\",\"year\":\"2011\",\"volume\":\"107\",\"id\":\"04baa759-4863-3a0b-9c40-df596776fcb3\",\"created\":\"2020-08-20T19:55:39.642Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.642Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"In this Letter, we investigate the number of measurement and communication rounds needed to implement certain tasks by local quantum operations and classical communication (LOCC), a relatively unexplored topic. To demonstrate the possible strong dependence on the round number, we consider the problem of converting three-qubit entanglement into two-qubit form, specifically in the random distillation setting of. We find that the number of LOCC rounds needed for a transformation can depend on the amount of entanglement distilled. In fact, for a wide range of transformations, the required number of rounds is infinite (unbounded). This represents the first concrete example of a task needing an infinite number of rounds to implement. © 2011 American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E.\",\"doi\":\"10.1103/PhysRevLett.107.190502\",\"journal\":\"Physical Review Letters\",\"number\":\"19\",\"bibtex\":\"@article{\\n title = {Local quantum transformations requiring infinite rounds of classical communication},\\n type = {article},\\n year = {2011},\\n volume = {107},\\n id = {04baa759-4863-3a0b-9c40-df596776fcb3},\\n created = {2020-08-20T19:55:39.642Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.642Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {In this Letter, we investigate the number of measurement and communication rounds needed to implement certain tasks by local quantum operations and classical communication (LOCC), a relatively unexplored topic. To demonstrate the possible strong dependence on the round number, we consider the problem of converting three-qubit entanglement into two-qubit form, specifically in the random distillation setting of. We find that the number of LOCC rounds needed for a transformation can depend on the amount of entanglement distilled. In fact, for a wide range of transformations, the required number of rounds is infinite (unbounded). This represents the first concrete example of a task needing an infinite number of rounds to implement. © 2011 American Physical Society.},\\n bibtype = {article},\\n author = {Chitambar, E.},\\n doi = {10.1103/PhysRevLett.107.190502},\\n journal = {Physical Review Letters},\\n number = {19}\\n}\",\"author_short\":[\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-localquantumtransformationsrequiringinfiniteroundsofclassicalcommunication-2011\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Bounds on Instantaneous Nonlocal Quantum Computation\",\"type\":\"article\",\"year\":\"2020\",\"keywords\":\"Quantum entanglement,quantum computing,teleportation\",\"volume\":\"66\",\"id\":\"f1f63484-2a06-357f-9ed5-e7abb9843e18\",\"created\":\"2020-08-20T19:55:39.652Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.652Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 1963-2012 IEEE. Instantaneous nonlocal quantum computation refers to a process in which spacelike separated parties simulate a nonlocal quantum operation on their joint systems through the consumption of pre-shared entanglement. To prevent a violation of causality, this simulation succeeds up to local errors that can only be corrected after the parties communicate classically with one another. However, this communication is non-interactive, and it involves just the broadcasting of local measurement outcomes. We refer to this operational paradigm as local operations and broadcast communication (LOBC) to distinguish it from the standard local operations and (interactive) classical communication (LOCC). In this paper, we show that an arbitrary two-qubit gate can be implemented by LOBC with $\\\\epsilon $ -error using $O(\\\\log (1/\\\\epsilon))$ entangled bits (ebits). This offers an exponential improvement over the best known two-qubit protocols, whose ebit costs behave as $O(1/\\\\epsilon)$. We also consider the family of binary controlled gates on dimensions $d_A\\\\otimes d_B$. We find that any hermitian gate of this form can be implemented by LOBC using a single shared ebit. In sharp contrast, a lower bound of $\\\\log d_B$ ebits is shown in the case of generic (i.e. non-hermitian) gates from this family, even when $d_A=2$. This demonstrates an unbounded gap between the entanglement costs of LOCC and LOBC gate implementation. Whereas previous lower bounds on the entanglement cost for instantaneous nonlocal computation restrict the minimum dimension of the needed entanglement, we bound its entanglement entropy. To our knowledge this is the first such lower bound of its kind.\",\"bibtype\":\"article\",\"author\":\"Gonzales, A. and Chitambar, E.\",\"doi\":\"10.1109/TIT.2019.2950190\",\"journal\":\"IEEE Transactions on Information Theory\",\"number\":\"5\",\"bibtex\":\"@article{\\n title = {Bounds on Instantaneous Nonlocal Quantum Computation},\\n type = {article},\\n year = {2020},\\n keywords = {Quantum entanglement,quantum computing,teleportation},\\n volume = {66},\\n id = {f1f63484-2a06-357f-9ed5-e7abb9843e18},\\n created = {2020-08-20T19:55:39.652Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.652Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 1963-2012 IEEE. Instantaneous nonlocal quantum computation refers to a process in which spacelike separated parties simulate a nonlocal quantum operation on their joint systems through the consumption of pre-shared entanglement. To prevent a violation of causality, this simulation succeeds up to local errors that can only be corrected after the parties communicate classically with one another. However, this communication is non-interactive, and it involves just the broadcasting of local measurement outcomes. We refer to this operational paradigm as local operations and broadcast communication (LOBC) to distinguish it from the standard local operations and (interactive) classical communication (LOCC). In this paper, we show that an arbitrary two-qubit gate can be implemented by LOBC with $\\\\epsilon $ -error using $O(\\\\log (1/\\\\epsilon))$ entangled bits (ebits). This offers an exponential improvement over the best known two-qubit protocols, whose ebit costs behave as $O(1/\\\\epsilon)$. We also consider the family of binary controlled gates on dimensions $d_A\\\\otimes d_B$. We find that any hermitian gate of this form can be implemented by LOBC using a single shared ebit. In sharp contrast, a lower bound of $\\\\log d_B$ ebits is shown in the case of generic (i.e. non-hermitian) gates from this family, even when $d_A=2$. This demonstrates an unbounded gap between the entanglement costs of LOCC and LOBC gate implementation. Whereas previous lower bounds on the entanglement cost for instantaneous nonlocal computation restrict the minimum dimension of the needed entanglement, we bound its entanglement entropy. To our knowledge this is the first such lower bound of its kind.},\\n bibtype = {article},\\n author = {Gonzales, A. and Chitambar, E.},\\n doi = {10.1109/TIT.2019.2950190},\\n journal = {IEEE Transactions on Information Theory},\\n number = {5}\\n}\",\"author_short\":[\"Gonzales,  A.\",\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"gonzales-chitambar-boundsoninstantaneousnonlocalquantumcomputation-2020\",\"role\":\"author\",\"urls\":{},\"keyword\":[\"Quantum entanglement\",\"quantum computing\",\"teleportation\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":10,\"html\":\"\"},{\"title\":\"The zero-error entanglement cost is highly non-additive\",\"type\":\"article\",\"year\":\"2019\",\"volume\":\"60\",\"id\":\"fe105007-3da1-3889-b174-c572ef813619\",\"created\":\"2020-08-20T19:55:39.682Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.682Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2019 Author(s). The Schmidt number is an entanglement measure whose logarithm quantifies the zero-error entanglement cost of generating a given quantum state using local operations and classical communication. In this paper, we show that the Schmidt number is highly nonmultiplicative in the sense that for any integer n, there exist states whose Schmidt number remains constant when taking n copies of the given state. These states also provide a rare instance in which the regularized zero-error entanglement cost can be computed exactly. We then explore the question of increasing the Schmidt number by quantum operations. We describe a class of bipartite quantum operations that preserve the Schmidt number for pure state transformations, and yet they can increase the Schmidt number by an arbitrarily large amount when generating mixed states. Our results are obtained by making connections to the resource theory of quantum coherence and generalizing the class of dephasing-covariant incoherent operations to the bipartite setting.\",\"bibtype\":\"article\",\"author\":\"Yue, Q. and Chitambar, E.\",\"doi\":\"10.1063/1.5087815\",\"journal\":\"Journal of Mathematical Physics\",\"number\":\"11\",\"bibtex\":\"@article{\\n title = {The zero-error entanglement cost is highly non-additive},\\n type = {article},\\n year = {2019},\\n volume = {60},\\n id = {fe105007-3da1-3889-b174-c572ef813619},\\n created = {2020-08-20T19:55:39.682Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.682Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2019 Author(s). The Schmidt number is an entanglement measure whose logarithm quantifies the zero-error entanglement cost of generating a given quantum state using local operations and classical communication. In this paper, we show that the Schmidt number is highly nonmultiplicative in the sense that for any integer n, there exist states whose Schmidt number remains constant when taking n copies of the given state. These states also provide a rare instance in which the regularized zero-error entanglement cost can be computed exactly. We then explore the question of increasing the Schmidt number by quantum operations. We describe a class of bipartite quantum operations that preserve the Schmidt number for pure state transformations, and yet they can increase the Schmidt number by an arbitrarily large amount when generating mixed states. Our results are obtained by making connections to the resource theory of quantum coherence and generalizing the class of dephasing-covariant incoherent operations to the bipartite setting.},\\n bibtype = {article},\\n author = {Yue, Q. and Chitambar, E.},\\n doi = {10.1063/1.5087815},\\n journal = {Journal of Mathematical Physics},\\n number = {11}\\n}\",\"author_short\":[\"Yue,  Q.\",\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"yue-chitambar-thezeroerrorentanglementcostishighlynonadditive-2019\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":4,\"html\":\"\"},{\"title\":\"Quantum resource theories\",\"type\":\"article\",\"year\":\"2019\",\"volume\":\"91\",\"id\":\"477ef01c-0b7c-3d78-8f24-7203f9ec3770\",\"created\":\"2020-08-20T19:55:39.697Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.697Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2019 American Physical Society. Quantum resource theories (QRTs) offer a highly versatile and powerful framework for studying different phenomena in quantum physics. From quantum entanglement to quantum computation, resource theories can be used to quantify a desirable quantum effect, develop new protocols for its detection, and identify processes that optimize its use for a given application. Particularly, QRTs have revolutionized the way we think about familiar properties of physical systems such as entanglement, elevating them from being just interesting fundamental phenomena to being useful in performing practical tasks. The basic methodology of a general QRT involves partitioning all quantum states into two groups, one consisting of free states and the other consisting of resource states. Accompanying the set of free states is a collection of free quantum operations arising from natural restrictions placed on the physical system, restrictions that force the free operations to act invariantly on the set of free states. The QRT then studies what information processing tasks become possible using the restricted operations. Despite the large degree of freedom in how one defines the free states and free operations, unexpected similarities emerge among different QRTs in terms of resource measures and resource convertibility. As a result, objects that appear quite distinct on the surface, such as entanglement and quantum reference frames, appear to have great similarity on a deeper structural level. This article reviews the general framework of a quantum resource theory, focusing on common structural features, operational tasks, and resource measures. To illustrate these concepts, an overview is provided on some of the more commonly studied QRTs in the literature.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Gour, G.\",\"doi\":\"10.1103/RevModPhys.91.025001\",\"journal\":\"Reviews of Modern Physics\",\"number\":\"2\",\"bibtex\":\"@article{\\n title = {Quantum resource theories},\\n type = {article},\\n year = {2019},\\n volume = {91},\\n id = {477ef01c-0b7c-3d78-8f24-7203f9ec3770},\\n created = {2020-08-20T19:55:39.697Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.697Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2019 American Physical Society. Quantum resource theories (QRTs) offer a highly versatile and powerful framework for studying different phenomena in quantum physics. From quantum entanglement to quantum computation, resource theories can be used to quantify a desirable quantum effect, develop new protocols for its detection, and identify processes that optimize its use for a given application. Particularly, QRTs have revolutionized the way we think about familiar properties of physical systems such as entanglement, elevating them from being just interesting fundamental phenomena to being useful in performing practical tasks. The basic methodology of a general QRT involves partitioning all quantum states into two groups, one consisting of free states and the other consisting of resource states. Accompanying the set of free states is a collection of free quantum operations arising from natural restrictions placed on the physical system, restrictions that force the free operations to act invariantly on the set of free states. The QRT then studies what information processing tasks become possible using the restricted operations. Despite the large degree of freedom in how one defines the free states and free operations, unexpected similarities emerge among different QRTs in terms of resource measures and resource convertibility. As a result, objects that appear quite distinct on the surface, such as entanglement and quantum reference frames, appear to have great similarity on a deeper structural level. This article reviews the general framework of a quantum resource theory, focusing on common structural features, operational tasks, and resource measures. To illustrate these concepts, an overview is provided on some of the more commonly studied QRTs in the literature.},\\n bibtype = {article},\\n author = {Chitambar, E. and Gour, G.},\\n doi = {10.1103/RevModPhys.91.025001},\\n journal = {Reviews of Modern Physics},\\n number = {2}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Gour,  G.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-gour-quantumresourcetheories-2019\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":10,\"html\":\"\"},{\"title\":\"Comparing coherence and entanglement under resource non-generating unitary transformations\",\"type\":\"article\",\"year\":\"2018\",\"keywords\":\"cohering power,quantum coherence,quantum entanglement,quantum information\",\"volume\":\"51\",\"id\":\"f7bb0eaf-f4d5-3f1e-a28b-09e0911ac99d\",\"created\":\"2020-08-20T19:55:39.720Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.720Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2018 IOP Publishing Ltd. Quantum coherence is a fundamental property of quantum systems that can be studied within the framework of a quantum resource theory. From this resource-theoretic approach, many similarities emerge between coherence and quantum entanglement, the latter being another prominent quantum resource. In this paper, we study the relationship between coherence and entanglement from the perspective of resource loss/gain by unitary dynamics. Specifically we consider how much coherence can be either generated or destroyed on a bipartite system when the action is restricted to local unitary (LU) operations. For pure states, we find that the relative entropy of entanglement and the robustness of entanglement provide tight lower bounds on the amount of coherence that can be destroyed by LUs, as measured by the relative entropy and measures of coherence, respectively. This provides new operational interpretations of the entanglement entropy and robustness of entanglement in pure states as the minimal amount of coherence that persists when the system is subjected to LU transformations. We then study the amount of bipartite pure entanglement that can be either maximized or minimized when the action is restricted to a global incoherent operation. For two-qubit pure states, maximum and minimum are shown in terms of coefficients of given state with incoherent basis. Finally we consider a generalized version of the recently introduced CCP of a quantum channel.\",\"bibtype\":\"article\",\"author\":\"Takahashi, M. and Chitambar, E.\",\"doi\":\"10.1088/1751-8121/aacc5c\",\"journal\":\"Journal of Physics A: Mathematical and Theoretical\",\"number\":\"41\",\"bibtex\":\"@article{\\n title = {Comparing coherence and entanglement under resource non-generating unitary transformations},\\n type = {article},\\n year = {2018},\\n keywords = {cohering power,quantum coherence,quantum entanglement,quantum information},\\n volume = {51},\\n id = {f7bb0eaf-f4d5-3f1e-a28b-09e0911ac99d},\\n created = {2020-08-20T19:55:39.720Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.720Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2018 IOP Publishing Ltd. Quantum coherence is a fundamental property of quantum systems that can be studied within the framework of a quantum resource theory. From this resource-theoretic approach, many similarities emerge between coherence and quantum entanglement, the latter being another prominent quantum resource. In this paper, we study the relationship between coherence and entanglement from the perspective of resource loss/gain by unitary dynamics. Specifically we consider how much coherence can be either generated or destroyed on a bipartite system when the action is restricted to local unitary (LU) operations. For pure states, we find that the relative entropy of entanglement and the robustness of entanglement provide tight lower bounds on the amount of coherence that can be destroyed by LUs, as measured by the relative entropy and measures of coherence, respectively. This provides new operational interpretations of the entanglement entropy and robustness of entanglement in pure states as the minimal amount of coherence that persists when the system is subjected to LU transformations. We then study the amount of bipartite pure entanglement that can be either maximized or minimized when the action is restricted to a global incoherent operation. For two-qubit pure states, maximum and minimum are shown in terms of coefficients of given state with incoherent basis. Finally we consider a generalized version of the recently introduced CCP of a quantum channel.},\\n bibtype = {article},\\n author = {Takahashi, M. and Chitambar, E.},\\n doi = {10.1088/1751-8121/aacc5c},\\n journal = {Journal of Physics A: Mathematical and Theoretical},\\n number = {41}\\n}\",\"author_short\":[\"Takahashi,  M.\",\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"takahashi-chitambar-comparingcoherenceandentanglementunderresourcenongeneratingunitarytransformations-2018\",\"role\":\"author\",\"urls\":{},\"keyword\":[\"cohering power\",\"quantum coherence\",\"quantum entanglement\",\"quantum information\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"More nonlocality with less entanglement in Clauser-Horne-Shimony-Holt experiments using inefficient detectors\",\"type\":\"article\",\"year\":\"2018\",\"volume\":\"97\",\"id\":\"9f896e13-50f7-3da3-9e13-06a686ccbcc6\",\"created\":\"2020-08-20T19:55:39.738Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.738Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2018 American Physical Society. It is well-known that in certain scenarios weakly entangled states can generate stronger nonlocal effects than their maximally entangled counterparts. In this paper, we consider violations of the Clauser-Horne-Shimony-Holt (CHSH) inequality when one party has inefficient detectors, a scenario known as an asymmetric Bell experiment. For any fixed detection efficiency, we derive a simple upper bound on the entanglement needed to violate the inequality by more than some specified amount κ≥0. When κ=0, the amount of entanglement in all states violating the inequality goes to zero as the detection efficiency approaches 50% from above. We finally consider the scenario in which detection inefficiency arises for only one choice of local measurement. In this case, it is shown that the CHSH inequality can always be violated for any nonzero detection efficiency and any choice of noncommuting measurements.\",\"bibtype\":\"article\",\"author\":\"Dilley, D. and Chitambar, E.\",\"doi\":\"10.1103/PhysRevA.97.062313\",\"journal\":\"Physical Review A\",\"number\":\"6\",\"bibtex\":\"@article{\\n title = {More nonlocality with less entanglement in Clauser-Horne-Shimony-Holt experiments using inefficient detectors},\\n type = {article},\\n year = {2018},\\n volume = {97},\\n id = {9f896e13-50f7-3da3-9e13-06a686ccbcc6},\\n created = {2020-08-20T19:55:39.738Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.738Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2018 American Physical Society. It is well-known that in certain scenarios weakly entangled states can generate stronger nonlocal effects than their maximally entangled counterparts. In this paper, we consider violations of the Clauser-Horne-Shimony-Holt (CHSH) inequality when one party has inefficient detectors, a scenario known as an asymmetric Bell experiment. For any fixed detection efficiency, we derive a simple upper bound on the entanglement needed to violate the inequality by more than some specified amount κ≥0. When κ=0, the amount of entanglement in all states violating the inequality goes to zero as the detection efficiency approaches 50% from above. We finally consider the scenario in which detection inefficiency arises for only one choice of local measurement. In this case, it is shown that the CHSH inequality can always be violated for any nonzero detection efficiency and any choice of noncommuting measurements.},\\n bibtype = {article},\\n author = {Dilley, D. and Chitambar, E.},\\n doi = {10.1103/PhysRevA.97.062313},\\n journal = {Physical Review A},\\n number = {6}\\n}\",\"author_short\":[\"Dilley,  D.\",\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"dilley-chitambar-morenonlocalitywithlessentanglementinclauserhorneshimonyholtexperimentsusinginefficientdetectors-2018\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":1,\"html\":\"\"},{\"title\":\"Round complexity in the local transformations of quantum and classical states\",\"type\":\"article\",\"year\":\"2017\",\"volume\":\"8\",\"id\":\"33eb12e6-a036-3823-afbc-f9af47594bcc\",\"created\":\"2020-08-20T19:55:39.761Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.761Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2017 The Author(s). In distributed quantum and classical information processing, spatially separated parties operate locally on their respective subsystems, but coordinate their actions through multiple exchanges of public communication. With interaction, the parties can perform more tasks. But how the exact number and order of exchanges enhances their operational capabilities is not well understood. Here we consider the minimum number of communication rounds needed to perform the locality-constrained tasks of entanglement transformation and its classical analog of secrecy manipulation. We provide an explicit construction of both quantum and classical state transformations which, for any given r, can be achieved using r rounds of classical communication exchanges, but no fewer. To show this, we build on the common structure underlying both resource theories of quantum entanglement and classical secret key. Our results reveal that highly complex communication protocols are indeed necessary to fully harness the information-theoretic resources contained in general quantum and classical states.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Hsieh, M.-H.\",\"doi\":\"10.1038/s41467-017-01887-5\",\"journal\":\"Nature Communications\",\"number\":\"1\",\"bibtex\":\"@article{\\n title = {Round complexity in the local transformations of quantum and classical states},\\n type = {article},\\n year = {2017},\\n volume = {8},\\n id = {33eb12e6-a036-3823-afbc-f9af47594bcc},\\n created = {2020-08-20T19:55:39.761Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.761Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2017 The Author(s). In distributed quantum and classical information processing, spatially separated parties operate locally on their respective subsystems, but coordinate their actions through multiple exchanges of public communication. With interaction, the parties can perform more tasks. But how the exact number and order of exchanges enhances their operational capabilities is not well understood. Here we consider the minimum number of communication rounds needed to perform the locality-constrained tasks of entanglement transformation and its classical analog of secrecy manipulation. We provide an explicit construction of both quantum and classical state transformations which, for any given r, can be achieved using r rounds of classical communication exchanges, but no fewer. To show this, we build on the common structure underlying both resource theories of quantum entanglement and classical secret key. Our results reveal that highly complex communication protocols are indeed necessary to fully harness the information-theoretic resources contained in general quantum and classical states.},\\n bibtype = {article},\\n author = {Chitambar, E. and Hsieh, M.-H.},\\n doi = {10.1038/s41467-017-01887-5},\\n journal = {Nature Communications},\\n number = {1}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Hsieh,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-hsieh-roundcomplexityinthelocaltransformationsofquantumandclassicalstates-2017\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":2,\"html\":\"\"},{\"title\":\"Comparison of incoherent operations and measures of coherence\",\"type\":\"article\",\"year\":\"2016\",\"volume\":\"94\",\"id\":\"4a0d2efa-8608-36a8-bbe3-55558cb82f54\",\"created\":\"2020-08-20T19:55:39.782Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.782Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2016 American Physical Society. A resource theory of quantum coherence attempts to characterize the quantum coherence that exists in a given quantum system. Many different approaches to a resource theory of coherence have recently been proposed, with their differences lying primarily in the identification of \\\"free\\\" or \\\"incoherent\\\" operations. In this article, we compare a number of these operational classes. In particular, the recently introduced class of dephasing-covariant operations is analyzed, and we characterize the Kraus operators of such maps. A number of coherence measures are introduced based on relative Rényi entropies, and we study incoherent state transformations under different operational classes. In particular, we show that the incoherent Schmidt rank can be increased arbitrarily large by certain noncoherence generating operations. The distinction between asymmetry-based versus basis-dependent notions of coherence theory is clarified, and we further develop the resource theory of N asymmetry, where N is the group of all diagonal incoherent unitaries.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Gour, G.\",\"doi\":\"10.1103/PhysRevA.94.052336\",\"journal\":\"Physical Review A\",\"number\":\"5\",\"bibtex\":\"@article{\\n title = {Comparison of incoherent operations and measures of coherence},\\n type = {article},\\n year = {2016},\\n volume = {94},\\n id = {4a0d2efa-8608-36a8-bbe3-55558cb82f54},\\n created = {2020-08-20T19:55:39.782Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.782Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2016 American Physical Society. A resource theory of quantum coherence attempts to characterize the quantum coherence that exists in a given quantum system. Many different approaches to a resource theory of coherence have recently been proposed, with their differences lying primarily in the identification of \\\"free\\\" or \\\"incoherent\\\" operations. In this article, we compare a number of these operational classes. In particular, the recently introduced class of dephasing-covariant operations is analyzed, and we characterize the Kraus operators of such maps. A number of coherence measures are introduced based on relative Rényi entropies, and we study incoherent state transformations under different operational classes. In particular, we show that the incoherent Schmidt rank can be increased arbitrarily large by certain noncoherence generating operations. The distinction between asymmetry-based versus basis-dependent notions of coherence theory is clarified, and we further develop the resource theory of N asymmetry, where N is the group of all diagonal incoherent unitaries.},\\n bibtype = {article},\\n author = {Chitambar, E. and Gour, G.},\\n doi = {10.1103/PhysRevA.94.052336},\\n journal = {Physical Review A},\\n number = {5}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Gour,  G.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-gour-comparisonofincoherentoperationsandmeasuresofcoherence-2016\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Critical Examination of Incoherent Operations and a Physically Consistent Resource Theory of Quantum Coherence\",\"type\":\"article\",\"year\":\"2016\",\"volume\":\"117\",\"id\":\"8613c0c1-11a3-3e12-8d45-a4a2242ed25f\",\"created\":\"2020-08-20T19:55:39.805Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.805Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2016 American Physical Society. Considerable work has recently been directed toward developing resource theories of quantum coherence. In this Letter, we establish a criterion of physical consistency for any resource theory. This criterion requires that all free operations in a given resource theory be implementable by a unitary evolution and projective measurement that are both free operations in an extended resource theory. We show that all currently proposed basis-dependent theories of coherence fail to satisfy this criterion. We further characterize the physically consistent resource theory of coherence and find its operational power to be quite limited. After relaxing the condition of physical consistency, we introduce the class of dephasing-covariant incoherent operations as a natural generalization of the physically consistent operations. Necessary and sufficient conditions are derived for the convertibility of qubit states using dephasing-covariant operations, and we show that these conditions also hold for other well-known classes of incoherent operations.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Gour, G.\",\"doi\":\"10.1103/PhysRevLett.117.030401\",\"journal\":\"Physical Review Letters\",\"number\":\"3\",\"bibtex\":\"@article{\\n title = {Critical Examination of Incoherent Operations and a Physically Consistent Resource Theory of Quantum Coherence},\\n type = {article},\\n year = {2016},\\n volume = {117},\\n id = {8613c0c1-11a3-3e12-8d45-a4a2242ed25f},\\n created = {2020-08-20T19:55:39.805Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.805Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2016 American Physical Society. Considerable work has recently been directed toward developing resource theories of quantum coherence. In this Letter, we establish a criterion of physical consistency for any resource theory. This criterion requires that all free operations in a given resource theory be implementable by a unitary evolution and projective measurement that are both free operations in an extended resource theory. We show that all currently proposed basis-dependent theories of coherence fail to satisfy this criterion. We further characterize the physically consistent resource theory of coherence and find its operational power to be quite limited. After relaxing the condition of physical consistency, we introduce the class of dephasing-covariant incoherent operations as a natural generalization of the physically consistent operations. Necessary and sufficient conditions are derived for the convertibility of qubit states using dephasing-covariant operations, and we show that these conditions also hold for other well-known classes of incoherent operations.},\\n bibtype = {article},\\n author = {Chitambar, E. and Gour, G.},\\n doi = {10.1103/PhysRevLett.117.030401},\\n journal = {Physical Review Letters},\\n number = {3}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Gour,  G.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-gour-criticalexaminationofincoherentoperationsandaphysicallyconsistentresourcetheoryofquantumcoherence-2016\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Relating the Resource Theories of Entanglement and Quantum Coherence\",\"type\":\"article\",\"year\":\"2016\",\"volume\":\"117\",\"id\":\"baf627f0-b9bb-392b-992f-c2d139e6b7e6\",\"created\":\"2020-08-20T19:55:39.824Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.824Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2016 American Physical Society. Quantum coherence and quantum entanglement represent two fundamental features of nonclassical systems that can each be characterized within an operational resource theory. In this Letter, we unify the resource theories of entanglement and coherence by studying their combined behavior in the operational setting of local incoherent operations and classical communication (LIOCC). Specifically, we analyze the coherence and entanglement trade-offs in the tasks of state formation and resource distillation. For pure states we identify the minimum coherence-entanglement resources needed to generate a given state, and we introduce a new LIOCC monotone that completely characterizes a state's optimal rate of bipartite coherence distillation. This result allows us to precisely quantify the difference in operational powers between global incoherent operations, LIOCC, and local incoherent operations without classical communication. Finally, a bipartite mixed state is shown to have distillable entanglement if and only if entanglement can be distilled by LIOCC, and we strengthen the well-known Horodecki criterion for distillability.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Hsieh, M.-H.\",\"doi\":\"10.1103/PhysRevLett.117.020402\",\"journal\":\"Physical Review Letters\",\"number\":\"2\",\"bibtex\":\"@article{\\n title = {Relating the Resource Theories of Entanglement and Quantum Coherence},\\n type = {article},\\n year = {2016},\\n volume = {117},\\n id = {baf627f0-b9bb-392b-992f-c2d139e6b7e6},\\n created = {2020-08-20T19:55:39.824Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.824Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2016 American Physical Society. Quantum coherence and quantum entanglement represent two fundamental features of nonclassical systems that can each be characterized within an operational resource theory. In this Letter, we unify the resource theories of entanglement and coherence by studying their combined behavior in the operational setting of local incoherent operations and classical communication (LIOCC). Specifically, we analyze the coherence and entanglement trade-offs in the tasks of state formation and resource distillation. For pure states we identify the minimum coherence-entanglement resources needed to generate a given state, and we introduce a new LIOCC monotone that completely characterizes a state's optimal rate of bipartite coherence distillation. This result allows us to precisely quantify the difference in operational powers between global incoherent operations, LIOCC, and local incoherent operations without classical communication. Finally, a bipartite mixed state is shown to have distillable entanglement if and only if entanglement can be distilled by LIOCC, and we strengthen the well-known Horodecki criterion for distillability.},\\n bibtype = {article},\\n author = {Chitambar, E. and Hsieh, M.-H.},\\n doi = {10.1103/PhysRevLett.117.020402},\\n journal = {Physical Review Letters},\\n number = {2}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Hsieh,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-hsieh-relatingtheresourcetheoriesofentanglementandquantumcoherence-2016\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":2,\"html\":\"\"},{\"title\":\"Asymptotic state discrimination and a strict hierarchy in distinguishability norms\",\"type\":\"article\",\"year\":\"2014\",\"volume\":\"55\",\"id\":\"56338a86-377c-31b5-be61-0acb6f727ef9\",\"created\":\"2020-08-20T19:55:39.872Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.872Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2014 AIP Publishing LLC. In this paper, we consider the problem of discriminating quantum states by local operations and classical communication (LOCC) when an arbitrarily small amount of error is permitted. This paradigm is known as asymptotic state discrimination, and we derive necessary conditions for when two multipartite states of any size can be discriminated perfectly by asymptotic LOCC. We use this new criterion to prove a gap in the LOCC and separable distinguishability norms. We then turn to the operational advantage of using two-way classical communication over one-way communication in LOCC processing. With a simple two-qubit product state ensemble, we demonstrate a strict majorization of the two-way LOCC norm over the one-way norm.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Hsieh, M.-H.\",\"doi\":\"10.1063/1.4902027\",\"journal\":\"Journal of Mathematical Physics\",\"number\":\"11\",\"bibtex\":\"@article{\\n title = {Asymptotic state discrimination and a strict hierarchy in distinguishability norms},\\n type = {article},\\n year = {2014},\\n volume = {55},\\n id = {56338a86-377c-31b5-be61-0acb6f727ef9},\\n created = {2020-08-20T19:55:39.872Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.872Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2014 AIP Publishing LLC. In this paper, we consider the problem of discriminating quantum states by local operations and classical communication (LOCC) when an arbitrarily small amount of error is permitted. This paradigm is known as asymptotic state discrimination, and we derive necessary conditions for when two multipartite states of any size can be discriminated perfectly by asymptotic LOCC. We use this new criterion to prove a gap in the LOCC and separable distinguishability norms. We then turn to the operational advantage of using two-way classical communication over one-way communication in LOCC processing. With a simple two-qubit product state ensemble, we demonstrate a strict majorization of the two-way LOCC norm over the one-way norm.},\\n bibtype = {article},\\n author = {Chitambar, E. and Hsieh, M.-H.},\\n doi = {10.1063/1.4902027},\\n journal = {Journal of Mathematical Physics},\\n number = {11}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Hsieh,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-hsieh-asymptoticstatediscriminationandastricthierarchyindistinguishabilitynorms-2014\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":1,\"html\":\"\"},{\"title\":\"Bell inequalities with communication assistance\",\"type\":\"article\",\"year\":\"2014\",\"volume\":\"89\",\"id\":\"35f997e0-089f-3654-af0f-7ae62492f62a\",\"created\":\"2020-08-20T19:55:39.886Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.886Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"In this paper, we consider the possible correlations between two parties using local machines and shared randomness with an additional amount of classical communication. This is a continuation of the work initiated by Bacon and Toner [Phys. Rev. Lett. 90, 157904 (2003)PRLTAO0031-900710.1103/PhysRevLett. 90.157904] who characterized the correlation polytope for 2×2 measurement settings with binary outcomes plus one bit of communication. Here, we derive a complete set of Bell inequalities for 3×2 measurement settings and a shared bit of communication. When the communication direction is fixed, nine Bell inequalities characterize the correlation polytope, whereas when the communication direction is bidirectional, 143 inequalities describe the correlations. We then prove a tight lower bound on the amount of communication needed to simulate all no-signaling correlations for a given number of measurement settings. © 2014 American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Maxwell, K. and Chitambar, E.\",\"doi\":\"10.1103/PhysRevA.89.042108\",\"journal\":\"Physical Review A - Atomic, Molecular, and Optical Physics\",\"number\":\"4\",\"bibtex\":\"@article{\\n title = {Bell inequalities with communication assistance},\\n type = {article},\\n year = {2014},\\n volume = {89},\\n id = {35f997e0-089f-3654-af0f-7ae62492f62a},\\n created = {2020-08-20T19:55:39.886Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.886Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {In this paper, we consider the possible correlations between two parties using local machines and shared randomness with an additional amount of classical communication. This is a continuation of the work initiated by Bacon and Toner [Phys. Rev. Lett. 90, 157904 (2003)PRLTAO0031-900710.1103/PhysRevLett. 90.157904] who characterized the correlation polytope for 2×2 measurement settings with binary outcomes plus one bit of communication. Here, we derive a complete set of Bell inequalities for 3×2 measurement settings and a shared bit of communication. When the communication direction is fixed, nine Bell inequalities characterize the correlation polytope, whereas when the communication direction is bidirectional, 143 inequalities describe the correlations. We then prove a tight lower bound on the amount of communication needed to simulate all no-signaling correlations for a given number of measurement settings. © 2014 American Physical Society.},\\n bibtype = {article},\\n author = {Maxwell, K. and Chitambar, E.},\\n doi = {10.1103/PhysRevA.89.042108},\\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\\n number = {4}\\n}\",\"author_short\":[\"Maxwell,  K.\",\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"maxwell-chitambar-bellinequalitieswithcommunicationassistance-2014\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Revisiting the optimal detection of quantum information\",\"type\":\"article\",\"year\":\"2013\",\"volume\":\"88\",\"id\":\"8826f40d-6a51-3119-b381-d63ea00cab3b\",\"created\":\"2020-08-20T19:55:39.910Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.910Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"In 1991, Peres and Wootters wrote a seminal paper on the nonlocal processing of quantum information. We return to their classic problem and solve it in various contexts. Specifically, for discriminating the \\\"double trine\\\" ensemble with minimum error, we prove that global operations are more powerful than local operations with classical communication (LOCC). Even stronger, there exists a finite gap between the optimal LOCC probability and that obtainable by separable operations (SEP). Additionally we prove that a two-way, adaptive LOCC strategy can always beat a one-way protocol. Our results demonstrate \\\"nonlocality without entanglement\\\" in two-qubit pure states. © 2013 American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Hsieh, M.-H.\",\"doi\":\"10.1103/PhysRevA.88.020302\",\"journal\":\"Physical Review A - Atomic, Molecular, and Optical Physics\",\"number\":\"2\",\"bibtex\":\"@article{\\n title = {Revisiting the optimal detection of quantum information},\\n type = {article},\\n year = {2013},\\n volume = {88},\\n id = {8826f40d-6a51-3119-b381-d63ea00cab3b},\\n created = {2020-08-20T19:55:39.910Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.910Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {In 1991, Peres and Wootters wrote a seminal paper on the nonlocal processing of quantum information. We return to their classic problem and solve it in various contexts. Specifically, for discriminating the \\\"double trine\\\" ensemble with minimum error, we prove that global operations are more powerful than local operations with classical communication (LOCC). Even stronger, there exists a finite gap between the optimal LOCC probability and that obtainable by separable operations (SEP). Additionally we prove that a two-way, adaptive LOCC strategy can always beat a one-way protocol. Our results demonstrate \\\"nonlocality without entanglement\\\" in two-qubit pure states. © 2013 American Physical Society.},\\n bibtype = {article},\\n author = {Chitambar, E. and Hsieh, M.-H.},\\n doi = {10.1103/PhysRevA.88.020302},\\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\\n number = {2}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Hsieh,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-hsieh-revisitingtheoptimaldetectionofquantuminformation-2013\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":1,\"html\":\"\"},{\"title\":\"Nonlocal Entanglement Transformations Achievable by Separable Operations\",\"type\":\"article\",\"year\":\"2009\",\"volume\":\"103\",\"id\":\"0eba58dc-d2c5-3987-8054-189e1f7c81f4\",\"created\":\"2020-08-20T19:55:39.933Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.933Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"The weird phenomenon of \\\"quantum nonlocality without entanglement\\\" means that local quantum operations assisted by classical communication constitute a proper subset of the class of separable quantum operations. Despite considerable recent advances, little is known to what extent the class of separable operations differs from local quantum operations and classical communication. In this Letter we show that separable operations are generally stronger than local quantum operations and classical communication when distilling a mixed state into a pure entangled state and thus confirm the existence of entanglement monotones that can increase under separable operations. Our finding can also be interpreted as confirming the ability of separable operations to enhance the entanglement of mixed states relative to certain measures, a sensible but important fact that has never been rigorously proven before. © 2009 The American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Duan, R.\",\"doi\":\"10.1103/PhysRevLett.103.110502\",\"journal\":\"Physical Review Letters\",\"number\":\"11\",\"bibtex\":\"@article{\\n title = {Nonlocal Entanglement Transformations Achievable by Separable Operations},\\n type = {article},\\n year = {2009},\\n volume = {103},\\n id = {0eba58dc-d2c5-3987-8054-189e1f7c81f4},\\n created = {2020-08-20T19:55:39.933Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.933Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {The weird phenomenon of \\\"quantum nonlocality without entanglement\\\" means that local quantum operations assisted by classical communication constitute a proper subset of the class of separable quantum operations. Despite considerable recent advances, little is known to what extent the class of separable operations differs from local quantum operations and classical communication. In this Letter we show that separable operations are generally stronger than local quantum operations and classical communication when distilling a mixed state into a pure entangled state and thus confirm the existence of entanglement monotones that can increase under separable operations. Our finding can also be interpreted as confirming the ability of separable operations to enhance the entanglement of mixed states relative to certain measures, a sensible but important fact that has never been rigorously proven before. © 2009 The American Physical Society.},\\n bibtype = {article},\\n author = {Chitambar, E. and Duan, R.},\\n doi = {10.1103/PhysRevLett.103.110502},\\n journal = {Physical Review Letters},\\n number = {11}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Duan,  R.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-duan-nonlocalentanglementtransformationsachievablebyseparableoperations-2009\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":1,\"html\":\"\"},{\"title\":\"Complete Resource Theory of Quantum Incompatibility as Quantum Programmability\",\"type\":\"article\",\"year\":\"2020\",\"volume\":\"124\",\"id\":\"940a84ef-16a7-39bc-a6c7-976cccd706f0\",\"created\":\"2020-08-20T19:55:39.959Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:39.959Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2020 American Physical Society. Measurement incompatibility describes two or more quantum measurements whose expected joint outcome on a given system cannot be defined. This purely nonclassical phenomenon provides a necessary ingredient in many quantum information tasks such as violating a Bell inequality or nonlocally steering part of an entangled state. In this Letter, we characterize incompatibility in terms of programmable measurement devices and the general notion of quantum programmability. This refers to the temporal freedom a user has in issuing programs to a quantum device. For devices with a classical control and classical output, measurement incompatibility emerges as the essential quantum resource embodied in their functioning. Based on the processing of programmable measurement devices, we construct a quantum resource theory of incompatibility. A complete set of convertibility conditions for programmable devices is derived based on quantum state discrimination with postmeasurement information.\",\"bibtype\":\"article\",\"author\":\"Buscemi, F. and Chitambar, E. and Zhou, W.\",\"doi\":\"10.1103/PhysRevLett.124.120401\",\"journal\":\"Physical Review Letters\",\"number\":\"12\",\"bibtex\":\"@article{\\n title = {Complete Resource Theory of Quantum Incompatibility as Quantum Programmability},\\n type = {article},\\n year = {2020},\\n volume = {124},\\n id = {940a84ef-16a7-39bc-a6c7-976cccd706f0},\\n created = {2020-08-20T19:55:39.959Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:39.959Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2020 American Physical Society. Measurement incompatibility describes two or more quantum measurements whose expected joint outcome on a given system cannot be defined. This purely nonclassical phenomenon provides a necessary ingredient in many quantum information tasks such as violating a Bell inequality or nonlocally steering part of an entangled state. In this Letter, we characterize incompatibility in terms of programmable measurement devices and the general notion of quantum programmability. This refers to the temporal freedom a user has in issuing programs to a quantum device. For devices with a classical control and classical output, measurement incompatibility emerges as the essential quantum resource embodied in their functioning. Based on the processing of programmable measurement devices, we construct a quantum resource theory of incompatibility. A complete set of convertibility conditions for programmable devices is derived based on quantum state discrimination with postmeasurement information.},\\n bibtype = {article},\\n author = {Buscemi, F. and Chitambar, E. and Zhou, W.},\\n doi = {10.1103/PhysRevLett.124.120401},\\n journal = {Physical Review Letters},\\n number = {12}\\n}\",\"author_short\":[\"Buscemi,  F.\",\"Chitambar,  E.\",\"Zhou,  W.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"buscemi-chitambar-zhou-completeresourcetheoryofquantumincompatibilityasquantumprogrammability-2020\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"One-shot assisted concentration of coherence\",\"type\":\"article\",\"year\":\"2018\",\"keywords\":\"assisted concentration of coherence,quantum coherence,quantum information\",\"volume\":\"51\",\"id\":\"079b5cfa-bee5-32b7-93fd-b84a875d3e98\",\"created\":\"2020-08-20T19:55:40.010Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.010Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2018 IOP Publishing Ltd. We find one-shot bounds for concentration of maximally coherent states in the so called assisted scenario. In this setting, Bob is restricted to performing incoherent operations on his quantum system, however he is assisted by Alice, who holds a purification of Bob's state and can send classical data to him. We further show that in the asymptotic limit our one-shot bounds recover the previously computed rate of asymptotic assisted concentration.\",\"bibtype\":\"article\",\"author\":\"Vijayan, M.K. and Chitambar, E. and Hsieh, M.-H.\",\"doi\":\"10.1088/1751-8121/aadc21\",\"journal\":\"Journal of Physics A: Mathematical and Theoretical\",\"number\":\"41\",\"bibtex\":\"@article{\\n title = {One-shot assisted concentration of coherence},\\n type = {article},\\n year = {2018},\\n keywords = {assisted concentration of coherence,quantum coherence,quantum information},\\n volume = {51},\\n id = {079b5cfa-bee5-32b7-93fd-b84a875d3e98},\\n created = {2020-08-20T19:55:40.010Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.010Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2018 IOP Publishing Ltd. We find one-shot bounds for concentration of maximally coherent states in the so called assisted scenario. In this setting, Bob is restricted to performing incoherent operations on his quantum system, however he is assisted by Alice, who holds a purification of Bob's state and can send classical data to him. We further show that in the asymptotic limit our one-shot bounds recover the previously computed rate of asymptotic assisted concentration.},\\n bibtype = {article},\\n author = {Vijayan, M.K. and Chitambar, E. and Hsieh, M.-H.},\\n doi = {10.1088/1751-8121/aadc21},\\n journal = {Journal of Physics A: Mathematical and Theoretical},\\n number = {41}\\n}\",\"author_short\":[\"Vijayan,  M.\",\"Chitambar,  E.\",\"Hsieh,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"vijayan-chitambar-hsieh-oneshotassistedconcentrationofcoherence-2018\",\"role\":\"author\",\"urls\":{},\"keyword\":[\"assisted concentration of coherence\",\"quantum coherence\",\"quantum information\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":1,\"html\":\"\"},{\"title\":\"The Conditional Common Information in Classical and Quantum Secret Key Distillation\",\"type\":\"article\",\"year\":\"2018\",\"keywords\":\"Quantum cryptography,common information,quantum information,secret key distillation\",\"volume\":\"64\",\"id\":\"4afb2101-5389-3b82-96e6-109eb342fb4a\",\"created\":\"2020-08-20T19:55:40.028Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.028Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2018 IEEE. In this paper, we consider two extensions of the Gács-Körner common information to three variables, the conditional common information (cCI) and the coarse-grained conditional common information (ccCI). Both quantities are shown to be useful technical tools in the study of classical and quantum resource transformations. In particular, the ccCI is shown to have an operational interpretation as the optimal rate of secret key extraction from an eavesdropped classical source pXYZ when Alice (X) and Bob (Y) are unable to communicate but share common randomness with the eavesdropper Eve (Z). Moving to the quantum setting, we consider two different ways of generating a tripartite quantum state from classical correlations pXYZ : 1) coherent encodings ∑xyz√pxyz|xyz〉 and 2) incoherent encodings ∑xyzpxyz|xyz〉〈xyz|. We study how well can Alice and Bob extract secret key from these quantum sources using quantum operations compared with the extraction of key from the underlying classical sources pXYZ using classical operations. While the power of quantum mechanics increases Alice and Bob's ability to generate shared randomness, it also equips Eve with a greater arsenal of eavesdropping attacks. Therefore, it is not obvious who gains the greatest advantage for distilling secret key when replacing a classical source with a quantum one. We first demonstrate that the classical key rate of pXYZ is equivalent to the quantum key rate for an incoherent quantum encoding of the distribution. For coherent encodings, we next show that the classical and quantum rates are generally incomparable, and in fact, their difference can be arbitrarily large in either direction. Finally, we introduce a \\\"zoo\\\" of entangled tripartite states all characterized by the conditional common information of their encoded probability distributions. Remarkably, for these states almost all entanglement measures, such as Alice and Bob's entanglement cost, squashed entanglement, and relative entropy of entanglement, can be sharply bounded or even exactly expressed in terms of the conditional common information. In the latter case, we thus present a rare instance in which the various entropic entanglement measures of a quantum state can be explicitly calculated.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Fortescue, B. and Hsieh, M.-H.\",\"doi\":\"10.1109/TIT.2018.2851564\",\"journal\":\"IEEE Transactions on Information Theory\",\"number\":\"11\",\"bibtex\":\"@article{\\n title = {The Conditional Common Information in Classical and Quantum Secret Key Distillation},\\n type = {article},\\n year = {2018},\\n keywords = {Quantum cryptography,common information,quantum information,secret key distillation},\\n volume = {64},\\n id = {4afb2101-5389-3b82-96e6-109eb342fb4a},\\n created = {2020-08-20T19:55:40.028Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.028Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2018 IEEE. In this paper, we consider two extensions of the Gács-Körner common information to three variables, the conditional common information (cCI) and the coarse-grained conditional common information (ccCI). Both quantities are shown to be useful technical tools in the study of classical and quantum resource transformations. In particular, the ccCI is shown to have an operational interpretation as the optimal rate of secret key extraction from an eavesdropped classical source pXYZ when Alice (X) and Bob (Y) are unable to communicate but share common randomness with the eavesdropper Eve (Z). Moving to the quantum setting, we consider two different ways of generating a tripartite quantum state from classical correlations pXYZ : 1) coherent encodings ∑xyz√pxyz|xyz〉 and 2) incoherent encodings ∑xyzpxyz|xyz〉〈xyz|. We study how well can Alice and Bob extract secret key from these quantum sources using quantum operations compared with the extraction of key from the underlying classical sources pXYZ using classical operations. While the power of quantum mechanics increases Alice and Bob's ability to generate shared randomness, it also equips Eve with a greater arsenal of eavesdropping attacks. Therefore, it is not obvious who gains the greatest advantage for distilling secret key when replacing a classical source with a quantum one. We first demonstrate that the classical key rate of pXYZ is equivalent to the quantum key rate for an incoherent quantum encoding of the distribution. For coherent encodings, we next show that the classical and quantum rates are generally incomparable, and in fact, their difference can be arbitrarily large in either direction. Finally, we introduce a \\\"zoo\\\" of entangled tripartite states all characterized by the conditional common information of their encoded probability distributions. Remarkably, for these states almost all entanglement measures, such as Alice and Bob's entanglement cost, squashed entanglement, and relative entropy of entanglement, can be sharply bounded or even exactly expressed in terms of the conditional common information. In the latter case, we thus present a rare instance in which the various entropic entanglement measures of a quantum state can be explicitly calculated.},\\n bibtype = {article},\\n author = {Chitambar, E. and Fortescue, B. and Hsieh, M.-H.},\\n doi = {10.1109/TIT.2018.2851564},\\n journal = {IEEE Transactions on Information Theory},\\n number = {11}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Fortescue,  B.\",\"Hsieh,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-fortescue-hsieh-theconditionalcommoninformationinclassicalandquantumsecretkeydistillation-2018\",\"role\":\"author\",\"urls\":{},\"keyword\":[\"Quantum cryptography\",\"common information\",\"quantum information\",\"secret key distillation\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":1,\"html\":\"\"},{\"title\":\"Open system quantum evolution and the assumption of complete positivity (A Tutorial)\",\"type\":\"article\",\"year\":\"2016\",\"keywords\":\"Open quantum systems,dynamical maps,positive maps\",\"volume\":\"14\",\"id\":\"0e3bd8e9-092c-3e48-a9c5-fc92052e53b3\",\"created\":\"2020-08-20T19:55:40.049Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.049Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2016 World Scientific Publishing Company. Quantum systems which interact with an unknown environment cannot be described in terms of a unitary evolution on the system alone. For such evolution one can use a map from one density operator to another and use any other known information to model the system. Such maps are required to be positive (at least on their domain) - they take positive density operators to positive density operators - so as to be physically reasonable. A map Φ which is positive but not completely positive (CP) is one which takes positive operators to positive operators, but when extended by the identity In, i.e. In In⊗ Φ does not give a positive map for some In. The map is CP if and only if the extension is positive for all n. Recently some effort has been put forth to try to understand if, and/or, under what circumstances one might utilize a non-CP map. Here, after a tutorial-type introduction to maps from one density operator to another, some examples which do not fit the standard prescription (SP) for deriving a CP map are given. In cases where the physical system is constrained by some knowledge of the interaction, it is possible that the SP cannot be used directly. Our example is robust to changes in the initial and final conditions.\",\"bibtype\":\"article\",\"author\":\"Byrd, M. and Ceballos, R. and Chitambar, E.\",\"doi\":\"10.1142/S0219749916400232\",\"journal\":\"International Journal of Quantum Information\",\"number\":\"6\",\"bibtex\":\"@article{\\n title = {Open system quantum evolution and the assumption of complete positivity (A Tutorial)},\\n type = {article},\\n year = {2016},\\n keywords = {Open quantum systems,dynamical maps,positive maps},\\n volume = {14},\\n id = {0e3bd8e9-092c-3e48-a9c5-fc92052e53b3},\\n created = {2020-08-20T19:55:40.049Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.049Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2016 World Scientific Publishing Company. Quantum systems which interact with an unknown environment cannot be described in terms of a unitary evolution on the system alone. For such evolution one can use a map from one density operator to another and use any other known information to model the system. Such maps are required to be positive (at least on their domain) - they take positive density operators to positive density operators - so as to be physically reasonable. A map Φ which is positive but not completely positive (CP) is one which takes positive operators to positive operators, but when extended by the identity In, i.e. In In⊗ Φ does not give a positive map for some In. The map is CP if and only if the extension is positive for all n. Recently some effort has been put forth to try to understand if, and/or, under what circumstances one might utilize a non-CP map. Here, after a tutorial-type introduction to maps from one density operator to another, some examples which do not fit the standard prescription (SP) for deriving a CP map are given. In cases where the physical system is constrained by some knowledge of the interaction, it is possible that the SP cannot be used directly. Our example is robust to changes in the initial and final conditions.},\\n bibtype = {article},\\n author = {Byrd, M. and Ceballos, R. and Chitambar, E.},\\n doi = {10.1142/S0219749916400232},\\n journal = {International Journal of Quantum Information},\\n number = {6}\\n}\",\"author_short\":[\"Byrd,  M.\",\"Ceballos,  R.\",\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"byrd-ceballos-chitambar-opensystemquantumevolutionandtheassumptionofcompletepositivityatutorial-2016\",\"role\":\"author\",\"urls\":{},\"keyword\":[\"Open quantum systems\",\"dynamical maps\",\"positive maps\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"The private and public correlation cost of three random variables with collaboration\",\"type\":\"article\",\"year\":\"2016\",\"keywords\":\"Wyner common information,local operations and public communication,reverse shannon theorem,secret key cost\",\"volume\":\"62\",\"id\":\"13cefc10-8643-3c40-abc2-efddff4747c4\",\"created\":\"2020-08-20T19:55:40.072Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.072Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2016 IEEE. In this paper, we consider the problem of generating arbitrary three-party correlations from a combination of public and secret correlations. Two parties - called Alice and Bob - share perfectly correlated bits that are secret from a collaborating third party, Charlie. At the same time, all three parties have access to a separate source of correlated bits, and their goal is to convert these two resources into multiple copies of some given tripartite distribution ℙ(XYZ). We obtain a single-letter characterization of the tradeoff between public and private bits that are needed to achieve this task. The rate of private bits is shown to generalize Wyner's classic notion of common information held between a pair of random variables. The problem we consider can be contrasted fruitfully with the task of secrecy formation, in which ℙ(XYZ) is generated using public communication and local randomness but with Charlie functioning as an adversary instead of a collaborator. We describe in detail the differences between the collaborative and adversarial scenarios.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Hsieh, M.-H. and Winter, A.\",\"doi\":\"10.1109/TIT.2016.2530086\",\"journal\":\"IEEE Transactions on Information Theory\",\"number\":\"4\",\"bibtex\":\"@article{\\n title = {The private and public correlation cost of three random variables with collaboration},\\n type = {article},\\n year = {2016},\\n keywords = {Wyner common information,local operations and public communication,reverse shannon theorem,secret key cost},\\n volume = {62},\\n id = {13cefc10-8643-3c40-abc2-efddff4747c4},\\n created = {2020-08-20T19:55:40.072Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.072Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2016 IEEE. In this paper, we consider the problem of generating arbitrary three-party correlations from a combination of public and secret correlations. Two parties - called Alice and Bob - share perfectly correlated bits that are secret from a collaborating third party, Charlie. At the same time, all three parties have access to a separate source of correlated bits, and their goal is to convert these two resources into multiple copies of some given tripartite distribution ℙ(XYZ). We obtain a single-letter characterization of the tradeoff between public and private bits that are needed to achieve this task. The rate of private bits is shown to generalize Wyner's classic notion of common information held between a pair of random variables. The problem we consider can be contrasted fruitfully with the task of secrecy formation, in which ℙ(XYZ) is generated using public communication and local randomness but with Charlie functioning as an adversary instead of a collaborator. We describe in detail the differences between the collaborative and adversarial scenarios.},\\n bibtype = {article},\\n author = {Chitambar, E. and Hsieh, M.-H. and Winter, A.},\\n doi = {10.1109/TIT.2016.2530086},\\n journal = {IEEE Transactions on Information Theory},\\n number = {4}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Hsieh,  M.\",\"Winter,  A.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-hsieh-winter-theprivateandpubliccorrelationcostofthreerandomvariableswithcollaboration-2016\",\"role\":\"author\",\"urls\":{},\"keyword\":[\"Wyner common information\",\"local operations and public communication\",\"reverse shannon theorem\",\"secret key cost\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Distributions attaining secret key at a rate of the conditional mutual information\",\"type\":\"book\",\"year\":\"2015\",\"source\":\"Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)\",\"keywords\":\"Gàcs-Körner Common Information,Information-theoretic security,Public key agreement\",\"volume\":\"9216\",\"id\":\"3bb5d92c-fa13-3ef1-b853-8acd18d2561a\",\"created\":\"2020-08-20T19:55:40.096Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.096Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© International Association for Cryptologic Research 2015. In this paper we consider the problem of extracting secret key from an eavesdropped source pXY Z at a rate given by the conditional mutual information. We investigate this question under three different scenarios: (i) Alice (X) and Bob (Y) are unable to communicate but share common randomness with the eavesdropper Eve (Z), (ii) Alice and Bob are allowed one-way public communication, and (iii) Alice and Bob are allowed two-way public communication. Distributions having a key rate of the conditional mutual information are precisely those in which a “helping” Eve offers Alice and Bob no greater advantage for obtaining secret key than a fully adversarial one. For each of the above scenarios, strong necessary conditions are derived on the structure of distributions attaining a secret key rate of I(X: Y |Z). In obtaining our results, we completely solve the problem of secret key distillation under scenario (i) and identify H(S|Z) to be the optimal key rate using shared randomness, where S is the Gàcs-Körner Common Information. We thus provide an operational interpretation of the conditional Gàcs- Körner Common Information. Additionally, we introduce simple example distributions in which the rate I(X: Y |Z) is achievable if and only if two-way communication is allowed.\",\"bibtype\":\"book\",\"author\":\"Chitambar, E. and Fortescue, B. and Hsieh, M.-H.\",\"doi\":\"10.1007/978-3-662-48000-7_22\",\"bibtex\":\"@book{\\n title = {Distributions attaining secret key at a rate of the conditional mutual information},\\n type = {book},\\n year = {2015},\\n source = {Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)},\\n keywords = {Gàcs-Körner Common Information,Information-theoretic security,Public key agreement},\\n volume = {9216},\\n id = {3bb5d92c-fa13-3ef1-b853-8acd18d2561a},\\n created = {2020-08-20T19:55:40.096Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.096Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© International Association for Cryptologic Research 2015. In this paper we consider the problem of extracting secret key from an eavesdropped source pXY Z at a rate given by the conditional mutual information. We investigate this question under three different scenarios: (i) Alice (X) and Bob (Y) are unable to communicate but share common randomness with the eavesdropper Eve (Z), (ii) Alice and Bob are allowed one-way public communication, and (iii) Alice and Bob are allowed two-way public communication. Distributions having a key rate of the conditional mutual information are precisely those in which a “helping” Eve offers Alice and Bob no greater advantage for obtaining secret key than a fully adversarial one. For each of the above scenarios, strong necessary conditions are derived on the structure of distributions attaining a secret key rate of I(X: Y |Z). In obtaining our results, we completely solve the problem of secret key distillation under scenario (i) and identify H(S|Z) to be the optimal key rate using shared randomness, where S is the Gàcs-Körner Common Information. We thus provide an operational interpretation of the conditional Gàcs- Körner Common Information. Additionally, we introduce simple example distributions in which the rate I(X: Y |Z) is achievable if and only if two-way communication is allowed.},\\n bibtype = {book},\\n author = {Chitambar, E. and Fortescue, B. and Hsieh, M.-H.},\\n doi = {10.1007/978-3-662-48000-7_22}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Fortescue,  B.\",\"Hsieh,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-fortescue-hsieh-distributionsattainingsecretkeyatarateoftheconditionalmutualinformation-2015\",\"role\":\"author\",\"urls\":{},\"keyword\":[\"Gàcs-Körner Common Information\",\"Information-theoretic security\",\"Public key agreement\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Classical Analog to Entanglement Reversibility\",\"type\":\"article\",\"year\":\"2015\",\"volume\":\"115\",\"id\":\"3add2917-c28c-377b-9275-2a1cec39c388\",\"created\":\"2020-08-20T19:55:40.119Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.119Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2015 American Physical Society. In this Letter we study the problem of secrecy reversibility. This asks when two honest parties can distill secret bits from some tripartite distribution pXYZ and transform secret bits back into pXYZ at equal rates using local operation and public communication. This is the classical analog to the well-studied problem of reversibly concentrating and diluting entanglement in a quantum state. We identify the structure of distributions possessing reversible secrecy when one of the honest parties holds a binary distribution, and it is possible that all reversible distributions have this form. These distributions are more general than what is obtained by simply constructing a classical analog to the family of quantum states known to have reversible entanglement. An indispensable tool used in our analysis is a conditional form of the Gács-Körner common information.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Fortescue, B. and Hsieh, M.-H.\",\"doi\":\"10.1103/PhysRevLett.115.090501\",\"journal\":\"Physical Review Letters\",\"number\":\"9\",\"bibtex\":\"@article{\\n title = {Classical Analog to Entanglement Reversibility},\\n type = {article},\\n year = {2015},\\n volume = {115},\\n id = {3add2917-c28c-377b-9275-2a1cec39c388},\\n created = {2020-08-20T19:55:40.119Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.119Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2015 American Physical Society. In this Letter we study the problem of secrecy reversibility. This asks when two honest parties can distill secret bits from some tripartite distribution pXYZ and transform secret bits back into pXYZ at equal rates using local operation and public communication. This is the classical analog to the well-studied problem of reversibly concentrating and diluting entanglement in a quantum state. We identify the structure of distributions possessing reversible secrecy when one of the honest parties holds a binary distribution, and it is possible that all reversible distributions have this form. These distributions are more general than what is obtained by simply constructing a classical analog to the family of quantum states known to have reversible entanglement. An indispensable tool used in our analysis is a conditional form of the Gács-Körner common information.},\\n bibtype = {article},\\n author = {Chitambar, E. and Fortescue, B. and Hsieh, M.-H.},\\n doi = {10.1103/PhysRevLett.115.090501},\\n journal = {Physical Review Letters},\\n number = {9}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Fortescue,  B.\",\"Hsieh,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-fortescue-hsieh-classicalanalogtoentanglementreversibility-2015\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"When do local operations and classical communication suffice for two-qubit state discrimination?\",\"type\":\"article\",\"year\":\"2014\",\"keywords\":\"LOCC,nonlocality without entanglement,state discrimination,trine ensembles\",\"volume\":\"60\",\"id\":\"211f0fec-77a0-36de-ba4b-7ad78061dabb\",\"created\":\"2020-08-20T19:55:40.163Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.163Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"In this paper, we consider the conditions under which a given ensemble of two-qubit states can be optimally distinguished by local operations and classical communication (LOCC). We begin by completing the perfect distinguishability problem of two-qubit ensembles - both for separable operations and LOCC - by providing necessary and sufficient conditions for the perfect discrimination of one pure and one mixed state. Then, for the well-known task of minimum error discrimination, it is shown that almost all two-qubit ensembles consisting of three pure states cannot be optimally discriminated using LOCC. This is surprising considering that any two pure states can be distinguished optimally by LOCC. Special attention is given to ensembles that lack entanglement, and we prove an easy sufficient condition for when a set of three product states cannot be optimally distinguished by LOCC, thus providing new examples of the phenomenon known as non-locality without entanglement. We next consider an example of N parties who each share the same state but who are ignorant of its identity. The state is drawn from the rotationally invariant trine ensemble, and we establish a tight connection between the N-copy ensemble and Shor's lifted single-copy ensemble. For any finite N, we prove that optimal identification of the states cannot be achieved by LOCC; however, as N → ∞, LOCC can indeed discriminate the states optimally. This is the first result of its kind. Finally, we turn to the task of unambiguous discrimination and derive new lower bounds on the LOCC inconclusive probability for symmetric states. When applied to the double trine ensemble, this leads to a rather different distinguishability character than when the minimum error probability is considered. © 1963-2012 IEEE.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Duan, R. and Hsieh, M.-H.\",\"doi\":\"10.1109/TIT.2013.2295356\",\"journal\":\"IEEE Transactions on Information Theory\",\"number\":\"3\",\"bibtex\":\"@article{\\n title = {When do local operations and classical communication suffice for two-qubit state discrimination?},\\n type = {article},\\n year = {2014},\\n keywords = {LOCC,nonlocality without entanglement,state discrimination,trine ensembles},\\n volume = {60},\\n id = {211f0fec-77a0-36de-ba4b-7ad78061dabb},\\n created = {2020-08-20T19:55:40.163Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.163Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {In this paper, we consider the conditions under which a given ensemble of two-qubit states can be optimally distinguished by local operations and classical communication (LOCC). We begin by completing the perfect distinguishability problem of two-qubit ensembles - both for separable operations and LOCC - by providing necessary and sufficient conditions for the perfect discrimination of one pure and one mixed state. Then, for the well-known task of minimum error discrimination, it is shown that almost all two-qubit ensembles consisting of three pure states cannot be optimally discriminated using LOCC. This is surprising considering that any two pure states can be distinguished optimally by LOCC. Special attention is given to ensembles that lack entanglement, and we prove an easy sufficient condition for when a set of three product states cannot be optimally distinguished by LOCC, thus providing new examples of the phenomenon known as non-locality without entanglement. We next consider an example of N parties who each share the same state but who are ignorant of its identity. The state is drawn from the rotationally invariant trine ensemble, and we establish a tight connection between the N-copy ensemble and Shor's lifted single-copy ensemble. For any finite N, we prove that optimal identification of the states cannot be achieved by LOCC; however, as N → ∞, LOCC can indeed discriminate the states optimally. This is the first result of its kind. Finally, we turn to the task of unambiguous discrimination and derive new lower bounds on the LOCC inconclusive probability for symmetric states. When applied to the double trine ensemble, this leads to a rather different distinguishability character than when the minimum error probability is considered. © 1963-2012 IEEE.},\\n bibtype = {article},\\n author = {Chitambar, E. and Duan, R. and Hsieh, M.-H.},\\n doi = {10.1109/TIT.2013.2295356},\\n journal = {IEEE Transactions on Information Theory},\\n number = {3}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Duan,  R.\",\"Hsieh,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-duan-hsieh-whendolocaloperationsandclassicalcommunicationsufficefortwoqubitstatediscrimination-2014\",\"role\":\"author\",\"urls\":{},\"keyword\":[\"LOCC\",\"nonlocality without entanglement\",\"state discrimination\",\"trine ensembles\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Entanglement monotones for W-type states\",\"type\":\"article\",\"year\":\"2012\",\"volume\":\"85\",\"id\":\"9bfe29c1-d69b-3d97-a36d-e67f749c7517\",\"created\":\"2020-08-20T19:55:40.183Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.183Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"In this article, we extend recent results concerning random-pair Einstein-Podolsky-Rosen distillation and the operational gap between separable operations (SEPs) and local operations with classical communication (LOCC). In particular, we consider the problem of obtaining bipartite maximal entanglement from an N-qubit W-class state (i.e., that of the form √x 0|000+√x 1|100++√x n|00) when the target pairs are a priori unspecified. We show that when x 0=0, the optimal probabilities for SEPs can be computed using semidefinite programming. On the other hand, to bound the optimal probabilities achievable by LOCC, we introduce entanglement monotones defined on the N-qubit W class of states. The LOCC monotones we construct can be increased by SEPs, and in terms of transformation success probability, we are able to quantify a gap as large as 37% between the two classes. Additionally, we demonstrate transformations ρ -n→σ -n that are feasible by SEP for any n but impossible by LOCC. © 2012 American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Cui, W. and Lo, H.-K.\",\"doi\":\"10.1103/PhysRevA.85.062316\",\"journal\":\"Physical Review A - Atomic, Molecular, and Optical Physics\",\"number\":\"6\",\"bibtex\":\"@article{\\n title = {Entanglement monotones for W-type states},\\n type = {article},\\n year = {2012},\\n volume = {85},\\n id = {9bfe29c1-d69b-3d97-a36d-e67f749c7517},\\n created = {2020-08-20T19:55:40.183Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.183Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {In this article, we extend recent results concerning random-pair Einstein-Podolsky-Rosen distillation and the operational gap between separable operations (SEPs) and local operations with classical communication (LOCC). In particular, we consider the problem of obtaining bipartite maximal entanglement from an N-qubit W-class state (i.e., that of the form √x 0|000+√x 1|100++√x n|00) when the target pairs are a priori unspecified. We show that when x 0=0, the optimal probabilities for SEPs can be computed using semidefinite programming. On the other hand, to bound the optimal probabilities achievable by LOCC, we introduce entanglement monotones defined on the N-qubit W class of states. The LOCC monotones we construct can be increased by SEPs, and in terms of transformation success probability, we are able to quantify a gap as large as 37% between the two classes. Additionally, we demonstrate transformations ρ -n→σ -n that are feasible by SEP for any n but impossible by LOCC. © 2012 American Physical Society.},\\n bibtype = {article},\\n author = {Chitambar, E. and Cui, W. and Lo, H.-K.},\\n doi = {10.1103/PhysRevA.85.062316},\\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\\n number = {6}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Cui,  W.\",\"Lo,  H.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-cui-lo-entanglementmonotonesforwtypestates-2012\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Increasing entanglement monotones by separable operations\",\"type\":\"article\",\"year\":\"2012\",\"volume\":\"108\",\"id\":\"92f45f3d-87c7-38b3-ad64-61f91d182693\",\"created\":\"2020-08-20T19:55:40.206Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.206Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Quantum entanglement is fundamentally related to the operational setting of local quantum operations and classical communication (LOCC). A more general class of operations known as separable operations (SEP) is often employed to approximate LOCC, but the exact difference between LOCC and SEP is unknown. In this letter, we compare the two classes in performing particular tripartite to bipartite entanglement conversions and report a gap as large as 12.5% between SEP and LOCC, which is the first known appreciable gap between the classes. Our results rely on constructing a computable entanglement monotone with a clear operational meaning that, unlike all other such monotones previously studied, is not monotonic under SEP. Finally, we prove the curious fact that convergent sequences of LOCC protocols need not be LOCC feasible in the limit. © 2012 American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Cui, W. and Lo, H.-K.\",\"doi\":\"10.1103/PhysRevLett.108.240504\",\"journal\":\"Physical Review Letters\",\"number\":\"24\",\"bibtex\":\"@article{\\n title = {Increasing entanglement monotones by separable operations},\\n type = {article},\\n year = {2012},\\n volume = {108},\\n id = {92f45f3d-87c7-38b3-ad64-61f91d182693},\\n created = {2020-08-20T19:55:40.206Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.206Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Quantum entanglement is fundamentally related to the operational setting of local quantum operations and classical communication (LOCC). A more general class of operations known as separable operations (SEP) is often employed to approximate LOCC, but the exact difference between LOCC and SEP is unknown. In this letter, we compare the two classes in performing particular tripartite to bipartite entanglement conversions and report a gap as large as 12.5% between SEP and LOCC, which is the first known appreciable gap between the classes. Our results rely on constructing a computable entanglement monotone with a clear operational meaning that, unlike all other such monotones previously studied, is not monotonic under SEP. Finally, we prove the curious fact that convergent sequences of LOCC protocols need not be LOCC feasible in the limit. © 2012 American Physical Society.},\\n bibtype = {article},\\n author = {Chitambar, E. and Cui, W. and Lo, H.-K.},\\n doi = {10.1103/PhysRevLett.108.240504},\\n journal = {Physical Review Letters},\\n number = {24}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Cui,  W.\",\"Lo,  H.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-cui-lo-increasingentanglementmonotonesbyseparableoperations-2012\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Randomly distilling W-class states into general configurations of two-party entanglement\",\"type\":\"article\",\"year\":\"2011\",\"volume\":\"84\",\"id\":\"1fe832a4-4bc3-3bd3-a230-ba8150945c56\",\"created\":\"2020-08-20T19:55:40.250Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.250Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"In this article we obtain results for the task of converting a single N-qubit W-class state (of the form √x0|00...0+√x 1|10...0++√xN|00...1) into maximum entanglement shared between two random parties. Previous studies in random distillation have not considered how the particular choice of target pairs affects the transformation, and here we develop a strategy for distilling into general configurations of target pairs. We completely solve the problem of determining the optimal distillation probability for all three-qubit configurations and most four-qubit configurations when x0=0. Our proof involves deriving new entanglement monotones defined on the set of four-qubit W-class states. As an additional application of our results, we present new upper bounds for converting a generic W-class state into the standard W state |W N=√1N(|10...0++|00...1). © 2011 American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Cui, W. and Chitambar, E. and Lo, H.K.\",\"doi\":\"10.1103/PhysRevA.84.052301\",\"journal\":\"Physical Review A - Atomic, Molecular, and Optical Physics\",\"number\":\"5\",\"bibtex\":\"@article{\\n title = {Randomly distilling W-class states into general configurations of two-party entanglement},\\n type = {article},\\n year = {2011},\\n volume = {84},\\n id = {1fe832a4-4bc3-3bd3-a230-ba8150945c56},\\n created = {2020-08-20T19:55:40.250Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.250Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {In this article we obtain results for the task of converting a single N-qubit W-class state (of the form √x0|00...0+√x 1|10...0++√xN|00...1) into maximum entanglement shared between two random parties. Previous studies in random distillation have not considered how the particular choice of target pairs affects the transformation, and here we develop a strategy for distilling into general configurations of target pairs. We completely solve the problem of determining the optimal distillation probability for all three-qubit configurations and most four-qubit configurations when x0=0. Our proof involves deriving new entanglement monotones defined on the set of four-qubit W-class states. As an additional application of our results, we present new upper bounds for converting a generic W-class state into the standard W state |W N=√1N(|10...0++|00...1). © 2011 American Physical Society.},\\n bibtype = {article},\\n author = {Cui, W. and Chitambar, E. and Lo, H.K.},\\n doi = {10.1103/PhysRevA.84.052301},\\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\\n number = {5}\\n}\",\"author_short\":[\"Cui,  W.\",\"Chitambar,  E.\",\"Lo,  H.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"cui-chitambar-lo-randomlydistillingwclassstatesintogeneralconfigurationsoftwopartyentanglement-2011\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Deciding unitary equivalence between matrix polynomials and sets of bipartite quantum states\",\"type\":\"article\",\"year\":\"2011\",\"keywords\":\"H zbinden,Matrix polynomials,Schwartz-zippel lemma communicated by: S braunstei,Unitary transformations\",\"volume\":\"11\",\"id\":\"47f31127-0f1a-3734-9de4-a259ab05f43a\",\"created\":\"2020-08-20T19:55:40.263Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.263Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"In this brief report, we consider the equivalence between two sets of m + 1 bipartite quantum states under local unitary transformations. For pure states, this problem corresponds to the matrix algebra question of whether two degree m matrix polynomials are unitarily equivalent; i.e. UAiV† = Bi for 0 < i < m where U and V are unitary and (Ai, Bi) are arbitrary pairs of rectangular matrices. We present a randomized polynomial-time algorithm that solves this problem with an arbitrarily high success probability and outputs transforming matrices U and V. © Rinton Press.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Miller, C.A. and Shi, Y.\",\"journal\":\"Quantum Information and Computation\",\"number\":\"9-10\",\"bibtex\":\"@article{\\n title = {Deciding unitary equivalence between matrix polynomials and sets of bipartite quantum states},\\n type = {article},\\n year = {2011},\\n keywords = {H zbinden,Matrix polynomials,Schwartz-zippel lemma communicated by: S braunstei,Unitary transformations},\\n volume = {11},\\n id = {47f31127-0f1a-3734-9de4-a259ab05f43a},\\n created = {2020-08-20T19:55:40.263Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.263Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {In this brief report, we consider the equivalence between two sets of m + 1 bipartite quantum states under local unitary transformations. For pure states, this problem corresponds to the matrix algebra question of whether two degree m matrix polynomials are unitarily equivalent; i.e. UAiV† = Bi for 0 < i < m where U and V are unitary and (Ai, Bi) are arbitrary pairs of rectangular matrices. We present a randomized polynomial-time algorithm that solves this problem with an arbitrarily high success probability and outputs transforming matrices U and V. © Rinton Press.},\\n bibtype = {article},\\n author = {Chitambar, E. and Miller, C.A. and Shi, Y.},\\n journal = {Quantum Information and Computation},\\n number = {9-10}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Miller,  C.\",\"Shi,  Y.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-miller-shi-decidingunitaryequivalencebetweenmatrixpolynomialsandsetsofbipartitequantumstates-2011\",\"role\":\"author\",\"urls\":{},\"keyword\":[\"H zbinden\",\"Matrix polynomials\",\"Schwartz-zippel lemma communicated by: S braunstei\",\"Unitary transformations\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":1,\"html\":\"\"},{\"title\":\"Two local observables are sufficient to characterize maximally entangled states of N qubits\",\"type\":\"article\",\"year\":\"2011\",\"volume\":\"83\",\"id\":\"e68c1f66-9a74-3301-812a-ac73d93149ba\",\"created\":\"2020-08-20T19:55:40.291Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.291Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Maximally entangled states (MES) represent a valuable resource in quantum information processing. In N-qubit systems the MES are N-GHZ states [i.e., the collection of |GHZ N =1 √2(|00...0 +|11...1 )] and its local unitary (LU) equivalences. While it is well known that such states are uniquely stabilized by N commuting observables, in this article we consider the minimum number of noncommuting observables needed to characterize an N-qubit MES as the unique common eigenstate. Here, we prove, rather surprisingly, that in this general case any N-GHZ state can be uniquely stabilized by only two observables. Thus, for the task of MES certification, only two correlated measurements are required with each party observing the spin of his or her system along one of two directions. © 2011 American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Yan, F. and Gao, T. and Chitambar, E.\",\"doi\":\"10.1103/PhysRevA.83.022319\",\"journal\":\"Physical Review A - Atomic, Molecular, and Optical Physics\",\"number\":\"2\",\"bibtex\":\"@article{\\n title = {Two local observables are sufficient to characterize maximally entangled states of N qubits},\\n type = {article},\\n year = {2011},\\n volume = {83},\\n id = {e68c1f66-9a74-3301-812a-ac73d93149ba},\\n created = {2020-08-20T19:55:40.291Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.291Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Maximally entangled states (MES) represent a valuable resource in quantum information processing. In N-qubit systems the MES are N-GHZ states [i.e., the collection of |GHZ N =1 √2(|00...0 +|11...1 )] and its local unitary (LU) equivalences. While it is well known that such states are uniquely stabilized by N commuting observables, in this article we consider the minimum number of noncommuting observables needed to characterize an N-qubit MES as the unique common eigenstate. Here, we prove, rather surprisingly, that in this general case any N-GHZ state can be uniquely stabilized by only two observables. Thus, for the task of MES certification, only two correlated measurements are required with each party observing the spin of his or her system along one of two directions. © 2011 American Physical Society.},\\n bibtype = {article},\\n author = {Yan, F. and Gao, T. and Chitambar, E.},\\n doi = {10.1103/PhysRevA.83.022319},\\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\\n number = {2}\\n}\",\"author_short\":[\"Yan,  F.\",\"Gao,  T.\",\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"yan-gao-chitambar-twolocalobservablesaresufficienttocharacterizemaximallyentangledstatesofnqubits-2011\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":1,\"html\":\"\"},{\"title\":\"Optimal entanglement transformations among N-qubit W-class states\",\"type\":\"article\",\"year\":\"2010\",\"volume\":\"82\",\"id\":\"6229a88c-87ca-3b0b-b3d4-f6fa916311ca\",\"created\":\"2020-08-20T19:55:40.303Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.303Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"We investigate the physically allowed probabilities for transforming one N-partite W-class state to another by means of local operations assisted with classical communication. Recently, S. Kintaş and S. Turgut [J. Math. Phys.JMAPAQ0022-248810.1063/1.3481573 51, 092202 (2010)] obtained an upper bound for the maximum probability of transforming two such states. Here, we provide a simple sufficient and necessary condition for when this upper bound can be satisfied and, thus, when optimality of state transformation can be achieved. Our discussion involves obtaining lower bounds for the transformation of arbitrary W-class states and showing precisely when this bound saturates the bound of Kintaş and Turgut. Finally, we consider the question of transforming symmetric W-class states and find that, in general, the optimal one-shot procedure for converting two symmetric states requires a nonsymmetric filter by all the parties. © 2010 The American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Cui, W. and Chitambar, E. and Lo, H.-K.\",\"doi\":\"10.1103/PhysRevA.82.062314\",\"journal\":\"Physical Review A - Atomic, Molecular, and Optical Physics\",\"number\":\"6\",\"bibtex\":\"@article{\\n title = {Optimal entanglement transformations among N-qubit W-class states},\\n type = {article},\\n year = {2010},\\n volume = {82},\\n id = {6229a88c-87ca-3b0b-b3d4-f6fa916311ca},\\n created = {2020-08-20T19:55:40.303Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.303Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {We investigate the physically allowed probabilities for transforming one N-partite W-class state to another by means of local operations assisted with classical communication. Recently, S. Kintaş and S. Turgut [J. Math. Phys.JMAPAQ0022-248810.1063/1.3481573 51, 092202 (2010)] obtained an upper bound for the maximum probability of transforming two such states. Here, we provide a simple sufficient and necessary condition for when this upper bound can be satisfied and, thus, when optimality of state transformation can be achieved. Our discussion involves obtaining lower bounds for the transformation of arbitrary W-class states and showing precisely when this bound saturates the bound of Kintaş and Turgut. Finally, we consider the question of transforming symmetric W-class states and find that, in general, the optimal one-shot procedure for converting two symmetric states requires a nonsymmetric filter by all the parties. © 2010 The American Physical Society.},\\n bibtype = {article},\\n author = {Cui, W. and Chitambar, E. and Lo, H.-K.},\\n doi = {10.1103/PhysRevA.82.062314},\\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\\n number = {6}\\n}\",\"author_short\":[\"Cui,  W.\",\"Chitambar,  E.\",\"Lo,  H.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"cui-chitambar-lo-optimalentanglementtransformationsamongnqubitwclassstates-2010\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Matrix pencils and entanglement classification\",\"type\":\"article\",\"year\":\"2010\",\"volume\":\"51\",\"id\":\"83925ba3-bf80-30de-af87-c90c4eb550d6\",\"created\":\"2020-08-20T19:55:40.333Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.333Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Quantum entanglement plays a central role in quantum information processing. A main objective of the theory is to classify different types of entanglement according to their interconvertibility through manipulations that do not require additional entanglement to perform. While bipartite entanglement is well understood in this framework, the classification of entanglements among three or more subsystems is inherently much more difficult. In this paper, we study pure state entanglement in systems of dimension 2⊗m⊗n. Two states are considered equivalent if they can be reversibly converted from one to the other with a nonzero probability using only local quantum resources and classical communication (SLOCC). We introduce a connection between entanglement manipulations in these systems and the well-studied theory of matrix pencils. All previous attempts to study general SLOCC equivalence in such systems have relied on somewhat contrived techniques which fail to reveal the elegant structure of the problem that can be seen from the matrix pencil approach. Based on this method, we report the first polynomial-time algorithm for deciding when two 2⊗m⊗n states are SLOCC equivalent. We then proceed to present a canonical form for all 2⊗m⊗n states based on the matrix pencil construction such that two states are equivalent if and only if they have the same canonical form. Besides recovering the previously known 26 distinct SLOCC equivalence classes in 2⊗3⊗n systems, we also determine the hierarchy between these classes. © 2010 American Institute of Physics.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Miller, C.A. and Shi, Y.\",\"doi\":\"10.1063/1.3459069\",\"journal\":\"Journal of Mathematical Physics\",\"number\":\"7\",\"bibtex\":\"@article{\\n title = {Matrix pencils and entanglement classification},\\n type = {article},\\n year = {2010},\\n volume = {51},\\n id = {83925ba3-bf80-30de-af87-c90c4eb550d6},\\n created = {2020-08-20T19:55:40.333Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.333Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Quantum entanglement plays a central role in quantum information processing. A main objective of the theory is to classify different types of entanglement according to their interconvertibility through manipulations that do not require additional entanglement to perform. While bipartite entanglement is well understood in this framework, the classification of entanglements among three or more subsystems is inherently much more difficult. In this paper, we study pure state entanglement in systems of dimension 2⊗m⊗n. Two states are considered equivalent if they can be reversibly converted from one to the other with a nonzero probability using only local quantum resources and classical communication (SLOCC). We introduce a connection between entanglement manipulations in these systems and the well-studied theory of matrix pencils. All previous attempts to study general SLOCC equivalence in such systems have relied on somewhat contrived techniques which fail to reveal the elegant structure of the problem that can be seen from the matrix pencil approach. Based on this method, we report the first polynomial-time algorithm for deciding when two 2⊗m⊗n states are SLOCC equivalent. We then proceed to present a canonical form for all 2⊗m⊗n states based on the matrix pencil construction such that two states are equivalent if and only if they have the same canonical form. Besides recovering the previously known 26 distinct SLOCC equivalence classes in 2⊗3⊗n systems, we also determine the hierarchy between these classes. © 2010 American Institute of Physics.},\\n bibtype = {article},\\n author = {Chitambar, E. and Miller, C.A. and Shi, Y.},\\n doi = {10.1063/1.3459069},\\n journal = {Journal of Mathematical Physics},\\n number = {7}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Miller,  C.\",\"Shi,  Y.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-miller-shi-matrixpencilsandentanglementclassification-2010\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Multipartite-to-bipartite entanglement transformations and polynomial identity testing\",\"type\":\"article\",\"year\":\"2010\",\"volume\":\"81\",\"id\":\"3e32439c-f2a5-3109-ae5b-7e9faa269ef8\",\"created\":\"2020-08-20T19:55:40.339Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.339Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"We consider the problem of deciding if some multiparty entangled pure state can be converted, with a nonzero success probability, into a given bipartite pure state shared between two specified parties through local quantum operations and classical communication. We show that this question is equivalent to the well-known computational problem of deciding if a multivariate polynomial is identically zero. Efficient randomized algorithms developed to study the latter can thus be applied to our question. As a result, a given transformation is possible if and only if it is generically attainable by a simple randomized protocol. © 2010 The American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Duan, R. and Shi, Y.\",\"doi\":\"10.1103/PhysRevA.81.052310\",\"journal\":\"Physical Review A - Atomic, Molecular, and Optical Physics\",\"number\":\"5\",\"bibtex\":\"@article{\\n title = {Multipartite-to-bipartite entanglement transformations and polynomial identity testing},\\n type = {article},\\n year = {2010},\\n volume = {81},\\n id = {3e32439c-f2a5-3109-ae5b-7e9faa269ef8},\\n created = {2020-08-20T19:55:40.339Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.339Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {We consider the problem of deciding if some multiparty entangled pure state can be converted, with a nonzero success probability, into a given bipartite pure state shared between two specified parties through local quantum operations and classical communication. We show that this question is equivalent to the well-known computational problem of deciding if a multivariate polynomial is identically zero. Efficient randomized algorithms developed to study the latter can thus be applied to our question. As a result, a given transformation is possible if and only if it is generically attainable by a simple randomized protocol. © 2010 The American Physical Society.},\\n bibtype = {article},\\n author = {Chitambar, E. and Duan, R. and Shi, Y.},\\n doi = {10.1103/PhysRevA.81.052310},\\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\\n number = {5}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Duan,  R.\",\"Shi,  Y.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-duan-shi-multipartitetobipartiteentanglementtransformationsandpolynomialidentitytesting-2010\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":2,\"html\":\"\"},{\"title\":\"Tripartite entanglement transformations and tensor rank\",\"type\":\"article\",\"year\":\"2008\",\"volume\":\"101\",\"id\":\"ec321753-91c8-3e30-9965-f98723cabc89\",\"created\":\"2020-08-20T19:55:40.378Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.378Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"A basic question regarding quantum entangled states is whether one can be probabilistically converted to another through local operations and classical communication exclusively. While the answer for bipartite systems is known, we show that for tripartite systems, this question encodes some of the most challenging open problems in mathematics and computer science. In particular, we show that there is no easy general criterion to determine the feasibility, and in fact, the problem is NP hard. In addition, we find obtaining the most efficient algorithm for matrix multiplication to be precisely equivalent to determining the maximum rate to convert the Greenberger-Horne-Zeilinger state to a triangular distribution of three EPR states. Our results are based on connections between multipartite entanglement and tensor rank (also called Schmidt rank), a key concept in algebraic complexity theory. © 2008 The American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Duan, R. and Shi, Y.\",\"doi\":\"10.1103/PhysRevLett.101.140502\",\"journal\":\"Physical Review Letters\",\"number\":\"14\",\"bibtex\":\"@article{\\n title = {Tripartite entanglement transformations and tensor rank},\\n type = {article},\\n year = {2008},\\n volume = {101},\\n id = {ec321753-91c8-3e30-9965-f98723cabc89},\\n created = {2020-08-20T19:55:40.378Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.378Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {A basic question regarding quantum entangled states is whether one can be probabilistically converted to another through local operations and classical communication exclusively. While the answer for bipartite systems is known, we show that for tripartite systems, this question encodes some of the most challenging open problems in mathematics and computer science. In particular, we show that there is no easy general criterion to determine the feasibility, and in fact, the problem is NP hard. In addition, we find obtaining the most efficient algorithm for matrix multiplication to be precisely equivalent to determining the maximum rate to convert the Greenberger-Horne-Zeilinger state to a triangular distribution of three EPR states. Our results are based on connections between multipartite entanglement and tensor rank (also called Schmidt rank), a key concept in algebraic complexity theory. © 2008 The American Physical Society.},\\n bibtype = {article},\\n author = {Chitambar, E. and Duan, R. and Shi, Y.},\\n doi = {10.1103/PhysRevLett.101.140502},\\n journal = {Physical Review Letters},\\n number = {14}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Duan,  R.\",\"Shi,  Y.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-duan-shi-tripartiteentanglementtransformationsandtensorrank-2008\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":4,\"html\":\"\"},{\"title\":\"Channel activation of CHSH nonlocality\",\"type\":\"article\",\"year\":\"2020\",\"keywords\":\"Chsh breaking channel,Nonlocality breaking channel,Superactivation\",\"volume\":\"22\",\"id\":\"b44e6ebc-ae9f-39e8-b625-f296dc8897e3\",\"created\":\"2020-08-20T19:55:40.385Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.385Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2020 The Author(s). Published by IOP Publishing Ltd on behalf of the Institute of Physics and Deutsche Physikalische Gesellschaft. Quantum channels that break CHSH nonlocality on all input states are known as CHSH-breaking channels. In quantum networks, such channels are useless for distributing correlations that can violate the CHSH Inequality. Motivated by previous work on activation of nonlocality in quantum states, here we demonstrate an analogous activation of CHSH-breaking channels. That is, we show that certain pairs of CHSH-breaking channels are no longer CHSH-breaking when used in combination. We find that this type of activation can emerge in both uni-directional and bi-directional communication scenarios.\",\"bibtype\":\"article\",\"author\":\"Zhang, Y. and Bravo, R.A. and Lorenz, V.O. and Chitambar, E.\",\"doi\":\"10.1088/1367-2630/ab7bef\",\"journal\":\"New Journal of Physics\",\"number\":\"4\",\"bibtex\":\"@article{\\n title = {Channel activation of CHSH nonlocality},\\n type = {article},\\n year = {2020},\\n keywords = {Chsh breaking channel,Nonlocality breaking channel,Superactivation},\\n volume = {22},\\n id = {b44e6ebc-ae9f-39e8-b625-f296dc8897e3},\\n created = {2020-08-20T19:55:40.385Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.385Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2020 The Author(s). Published by IOP Publishing Ltd on behalf of the Institute of Physics and Deutsche Physikalische Gesellschaft. Quantum channels that break CHSH nonlocality on all input states are known as CHSH-breaking channels. In quantum networks, such channels are useless for distributing correlations that can violate the CHSH Inequality. Motivated by previous work on activation of nonlocality in quantum states, here we demonstrate an analogous activation of CHSH-breaking channels. That is, we show that certain pairs of CHSH-breaking channels are no longer CHSH-breaking when used in combination. We find that this type of activation can emerge in both uni-directional and bi-directional communication scenarios.},\\n bibtype = {article},\\n author = {Zhang, Y. and Bravo, R.A. and Lorenz, V.O. and Chitambar, E.},\\n doi = {10.1088/1367-2630/ab7bef},\\n journal = {New Journal of Physics},\\n number = {4}\\n}\",\"author_short\":[\"Zhang,  Y.\",\"Bravo,  R.\",\"Lorenz,  V.\",\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"zhang-bravo-lorenz-chitambar-channelactivationofchshnonlocality-2020\",\"role\":\"author\",\"urls\":{},\"keyword\":[\"Chsh breaking channel\",\"Nonlocality breaking channel\",\"Superactivation\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":7,\"html\":\"\"},{\"title\":\"Entanglement manipulation beyond local operations and classical communication\",\"type\":\"article\",\"year\":\"2020\",\"volume\":\"61\",\"id\":\"bd9a9d58-2c6a-308c-98f1-9cc68b2397f8\",\"created\":\"2020-08-20T19:55:40.423Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.423Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2020 Author(s). When a quantum system is distributed to spatially separated parties, it is natural to consider how the system evolves when the parties perform local quantum operations with classical communication (LOCC). However, the structure of LOCC channels is exceedingly complex, leaving many important physical problems unsolved. In this paper, we consider generalized resource theories of entanglement based on different relaxations to the class of LOCC. The behavior of various entanglement measures is studied under non-entangling channels, as well as the newly introduced classes of dually non-entangling and positive partial transpose (PPT)-preserving channels. In an effort to better understand the nature of LOCC bound entanglement, we study the problem of entanglement distillation in these generalized resource theories. We first show that unlike LOCC, general non-entangling maps can be superactivated, in the sense that two copies of the same non-entangling map can, nevertheless, be entangling. On the single-copy level, we demonstrate that every NPT entangled state can be converted into an LOCC-distillable state using channels that are both dually non-entangling and having a PPT Choi representation and that every state can be converted into an LOCC-distillable state using operations belonging to any family of polytopes that approximate LOCC. We then turn to the stochastic convertibility of multipartite pure states and show that any two states can be interconverted by any polytope approximation to the set of separable channels. Finally, as an analog to k-positive maps, we introduce and analyze the set of k-non-entangling channels.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and De Vicente, J.I. and Girard, M.W. and Gour, G.\",\"doi\":\"10.1063/1.5124109\",\"journal\":\"Journal of Mathematical Physics\",\"number\":\"4\",\"bibtex\":\"@article{\\n title = {Entanglement manipulation beyond local operations and classical communication},\\n type = {article},\\n year = {2020},\\n volume = {61},\\n id = {bd9a9d58-2c6a-308c-98f1-9cc68b2397f8},\\n created = {2020-08-20T19:55:40.423Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.423Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2020 Author(s). When a quantum system is distributed to spatially separated parties, it is natural to consider how the system evolves when the parties perform local quantum operations with classical communication (LOCC). However, the structure of LOCC channels is exceedingly complex, leaving many important physical problems unsolved. In this paper, we consider generalized resource theories of entanglement based on different relaxations to the class of LOCC. The behavior of various entanglement measures is studied under non-entangling channels, as well as the newly introduced classes of dually non-entangling and positive partial transpose (PPT)-preserving channels. In an effort to better understand the nature of LOCC bound entanglement, we study the problem of entanglement distillation in these generalized resource theories. We first show that unlike LOCC, general non-entangling maps can be superactivated, in the sense that two copies of the same non-entangling map can, nevertheless, be entangling. On the single-copy level, we demonstrate that every NPT entangled state can be converted into an LOCC-distillable state using channels that are both dually non-entangling and having a PPT Choi representation and that every state can be converted into an LOCC-distillable state using operations belonging to any family of polytopes that approximate LOCC. We then turn to the stochastic convertibility of multipartite pure states and show that any two states can be interconverted by any polytope approximation to the set of separable channels. Finally, as an analog to k-positive maps, we introduce and analyze the set of k-non-entangling channels.},\\n bibtype = {article},\\n author = {Chitambar, E. and De Vicente, J.I. and Girard, M.W. and Gour, G.},\\n doi = {10.1063/1.5124109},\\n journal = {Journal of Mathematical Physics},\\n number = {4}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"De Vicente,  J.\",\"Girard,  M.\",\"Gour,  G.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-devicente-girard-gour-entanglementmanipulationbeyondlocaloperationsandclassicalcommunication-2020\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":21,\"html\":\"\"},{\"title\":\"Restrictions on initial system-environment correlations based on the dynamics of an open quantum system\",\"type\":\"article\",\"year\":\"2015\",\"volume\":\"92\",\"id\":\"b3913c87-5a45-3b64-98f2-ea310ec10e78\",\"created\":\"2020-08-20T19:55:40.428Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.428Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2015 American Physical Society. The dynamics of an open quantum system is often modeled by introducing a bath initially in a product state with the system, letting the system and bath evolve unitarily together, and then tracing over the bath. However, often this model may not accurately reflect a particular experimental situation. Here, we provide some restrictions on one's ability to model an open quantum system using an initial product state when some information about the system-bath interaction is known. For instance, when certain symmetries exist in the system-bath interaction, we compute limitations on how much the system's purity can be increased if the bath is initially uncorrelated white noise. Furthermore, when the system and bath are qubits, we find that effectively only swap and product unitaries always generate system dynamics capable of being modeled using an initial product state. Finally, we show how any initial correlations between the system and environment are detectable, in principle, by observing the system transformation alone during certain joint evolutions. Our results have application in experimental quantum control and quantum computing where the system and environment are often assumed to be initially uncorrelated.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Abu-Nada, A. and Ceballos, R. and Byrd, M.\",\"doi\":\"10.1103/PhysRevA.92.052110\",\"journal\":\"Physical Review A - Atomic, Molecular, and Optical Physics\",\"number\":\"5\",\"bibtex\":\"@article{\\n title = {Restrictions on initial system-environment correlations based on the dynamics of an open quantum system},\\n type = {article},\\n year = {2015},\\n volume = {92},\\n id = {b3913c87-5a45-3b64-98f2-ea310ec10e78},\\n created = {2020-08-20T19:55:40.428Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.428Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2015 American Physical Society. The dynamics of an open quantum system is often modeled by introducing a bath initially in a product state with the system, letting the system and bath evolve unitarily together, and then tracing over the bath. However, often this model may not accurately reflect a particular experimental situation. Here, we provide some restrictions on one's ability to model an open quantum system using an initial product state when some information about the system-bath interaction is known. For instance, when certain symmetries exist in the system-bath interaction, we compute limitations on how much the system's purity can be increased if the bath is initially uncorrelated white noise. Furthermore, when the system and bath are qubits, we find that effectively only swap and product unitaries always generate system dynamics capable of being modeled using an initial product state. Finally, we show how any initial correlations between the system and environment are detectable, in principle, by observing the system transformation alone during certain joint evolutions. Our results have application in experimental quantum control and quantum computing where the system and environment are often assumed to be initially uncorrelated.},\\n bibtype = {article},\\n author = {Chitambar, E. and Abu-Nada, A. and Ceballos, R. and Byrd, M.},\\n doi = {10.1103/PhysRevA.92.052110},\\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\\n number = {5}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Abu-Nada,  A.\",\"Ceballos,  R.\",\"Byrd,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-abunada-ceballos-byrd-restrictionsoninitialsystemenvironmentcorrelationsbasedonthedynamicsofanopenquantumsystem-2015\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":1,\"html\":\"\"},{\"title\":\"Detecting multipartite classical states and their resemblances\",\"type\":\"article\",\"year\":\"2011\",\"volume\":\"83\",\"id\":\"ec0c19ae-d9ee-3052-97c2-978ccabfbecf\",\"created\":\"2020-08-20T19:55:40.466Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.466Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"We study various types of multipartite states lying near the quantum-classical boundary. The so-called classical states are precisely those in which each party can perfectly identify a locally held state without disturbing the global state, a task known as nondisruptive local state identification (NDLID). We show NDLID to be closely related local broadcasting, and we introduce a class of states called generalized classical states which allow for both NDLID and multipartite broadcasting when the most general quantum measurements are permitted. Simple analytical methods and a physical criterion are given for detecting whether a multipartite state is classical or generalized classical. For deciding the latter, a semidefinite programming algorithm is presented which may find use in other fields such as signal processing. © 2011 American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Chen, L. and Chitambar, E. and Modi, K. and Vacanti, G.\",\"doi\":\"10.1103/PhysRevA.83.020101\",\"journal\":\"Physical Review A - Atomic, Molecular, and Optical Physics\",\"number\":\"2\",\"bibtex\":\"@article{\\n title = {Detecting multipartite classical states and their resemblances},\\n type = {article},\\n year = {2011},\\n volume = {83},\\n id = {ec0c19ae-d9ee-3052-97c2-978ccabfbecf},\\n created = {2020-08-20T19:55:40.466Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.466Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {We study various types of multipartite states lying near the quantum-classical boundary. The so-called classical states are precisely those in which each party can perfectly identify a locally held state without disturbing the global state, a task known as nondisruptive local state identification (NDLID). We show NDLID to be closely related local broadcasting, and we introduce a class of states called generalized classical states which allow for both NDLID and multipartite broadcasting when the most general quantum measurements are permitted. Simple analytical methods and a physical criterion are given for detecting whether a multipartite state is classical or generalized classical. For deciding the latter, a semidefinite programming algorithm is presented which may find use in other fields such as signal processing. © 2011 American Physical Society.},\\n bibtype = {article},\\n author = {Chen, L. and Chitambar, E. and Modi, K. and Vacanti, G.},\\n doi = {10.1103/PhysRevA.83.020101},\\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\\n number = {2}\\n}\",\"author_short\":[\"Chen,  L.\",\"Chitambar,  E.\",\"Modi,  K.\",\"Vacanti,  G.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chen-chitambar-modi-vacanti-detectingmultipartiteclassicalstatesandtheirresemblances-2011\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":1,\"html\":\"\"},{\"title\":\"Tensor rank of the tripartite state |W n\",\"type\":\"article\",\"year\":\"2010\",\"volume\":\"81\",\"id\":\"d58fee13-3db1-3a9e-9623-377e7b12050c\",\"created\":\"2020-08-20T19:55:40.473Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.473Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Tensor rank refers to the number of product states needed to express a given multipartite quantum state. Its nonadditivity as an entanglement measure has recently been observed. In this Brief Report, we estimate the tensor rank of multiple copies of the tripartite state |W=13(|100+|010+|001). Both an upper bound and a lower bound of this rank are derived. In particular, it is proven that the rank of |W 2 is 7, thus resolving a previously open problem. Some implications of this result are discussed in terms of transformation rates between |Wn and multiple copies of the state |GHZ=12(|000+|111). © 2010 The American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Yu, N. and Chitambar, E. and Guo, C. and Duan, R.\",\"doi\":\"10.1103/PhysRevA.81.014301\",\"journal\":\"Physical Review A - Atomic, Molecular, and Optical Physics\",\"number\":\"1\",\"bibtex\":\"@article{\\n title = {Tensor rank of the tripartite state |W n},\\n type = {article},\\n year = {2010},\\n volume = {81},\\n id = {d58fee13-3db1-3a9e-9623-377e7b12050c},\\n created = {2020-08-20T19:55:40.473Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.473Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Tensor rank refers to the number of product states needed to express a given multipartite quantum state. Its nonadditivity as an entanglement measure has recently been observed. In this Brief Report, we estimate the tensor rank of multiple copies of the tripartite state |W=13(|100+|010+|001). Both an upper bound and a lower bound of this rank are derived. In particular, it is proven that the rank of |W 2 is 7, thus resolving a previously open problem. Some implications of this result are discussed in terms of transformation rates between |Wn and multiple copies of the state |GHZ=12(|000+|111). © 2010 The American Physical Society.},\\n bibtype = {article},\\n author = {Yu, N. and Chitambar, E. and Guo, C. and Duan, R.},\\n doi = {10.1103/PhysRevA.81.014301},\\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\\n number = {1}\\n}\",\"author_short\":[\"Yu,  N.\",\"Chitambar,  E.\",\"Guo,  C.\",\"Duan,  R.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"yu-chitambar-guo-duan-tensorrankofthetripartitestatewn-2010\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"One-Shot Coherence Distillation: Towards Completing the Picture\",\"type\":\"article\",\"year\":\"2019\",\"keywords\":\"Quantum coherence,coherence distillation,one-shot,quantum resource theory\",\"volume\":\"65\",\"id\":\"05d81eb1-a738-339e-9b07-4acb9ecdc99b\",\"created\":\"2020-08-20T19:55:40.513Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.513Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 1963-2012 IEEE. The resource framework of quantum coherence was introduced by Baumgratz, Cramer, and Plenio [Phys. Rev. Lett. 113, 140401 (2014)] and further developed by Winter and Yang [Phys. Rev. Lett. 116, 120404 (2016)]. We consider the one-shot problem of distilling pure coherence from a single instance of a given resource state. Specifically, we determine the distillable coherence with a given fidelity under incoherent operations (IO) through a generalization of the Winter-Yang protocol. This is compared to the distillable coherence under maximal incoherent operations (MIO) and dephasing-covariant incoherent operations (DIO), which can be cast as a semidefinite programme, that has been presented previously by Regula et al. [Phys. Rev. Lett. 121, 010401 (2018)]. Our results are given in terms of a smoothed min-relative entropy distance from the incoherent set of states, and a variant of the hypothesis-testing relative entropy distance, respectively. The one-shot distillable coherence is also related to one-shot randomness extraction. Moreover, from the one-shot formulas under IO, MIO, and DIO, we can recover the optimal distillable rate in the many-copy asymptotics, yielding the relative entropy of coherence. These results can be compared with previous work by some of the present authors [Zhao et al., Phys. Rev. Lett. 120, 070403 (2018)] on one-shot coherence formation under IO, MIO, DIO and also SIO. This shows that the amount of distillable coherence is essentially the same for IO, DIO, and MIO, despite the fact that the three classes of operations are very different. We also relate the distillable coherence under strictly incoherent operations (SIO) to a constrained hypothesis testing problem and explicitly show the existence of bound coherence under SIO in the asymptotic regime.\",\"bibtype\":\"article\",\"author\":\"Zhao, Q. and Liu, Y. and Yuan, X. and Chitambar, E. and Winter, A.\",\"doi\":\"10.1109/TIT.2019.2911102\",\"journal\":\"IEEE Transactions on Information Theory\",\"number\":\"10\",\"bibtex\":\"@article{\\n title = {One-Shot Coherence Distillation: Towards Completing the Picture},\\n type = {article},\\n year = {2019},\\n keywords = {Quantum coherence,coherence distillation,one-shot,quantum resource theory},\\n volume = {65},\\n id = {05d81eb1-a738-339e-9b07-4acb9ecdc99b},\\n created = {2020-08-20T19:55:40.513Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.513Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 1963-2012 IEEE. The resource framework of quantum coherence was introduced by Baumgratz, Cramer, and Plenio [Phys. Rev. Lett. 113, 140401 (2014)] and further developed by Winter and Yang [Phys. Rev. Lett. 116, 120404 (2016)]. We consider the one-shot problem of distilling pure coherence from a single instance of a given resource state. Specifically, we determine the distillable coherence with a given fidelity under incoherent operations (IO) through a generalization of the Winter-Yang protocol. This is compared to the distillable coherence under maximal incoherent operations (MIO) and dephasing-covariant incoherent operations (DIO), which can be cast as a semidefinite programme, that has been presented previously by Regula et al. [Phys. Rev. Lett. 121, 010401 (2018)]. Our results are given in terms of a smoothed min-relative entropy distance from the incoherent set of states, and a variant of the hypothesis-testing relative entropy distance, respectively. The one-shot distillable coherence is also related to one-shot randomness extraction. Moreover, from the one-shot formulas under IO, MIO, and DIO, we can recover the optimal distillable rate in the many-copy asymptotics, yielding the relative entropy of coherence. These results can be compared with previous work by some of the present authors [Zhao et al., Phys. Rev. Lett. 120, 070403 (2018)] on one-shot coherence formation under IO, MIO, DIO and also SIO. This shows that the amount of distillable coherence is essentially the same for IO, DIO, and MIO, despite the fact that the three classes of operations are very different. We also relate the distillable coherence under strictly incoherent operations (SIO) to a constrained hypothesis testing problem and explicitly show the existence of bound coherence under SIO in the asymptotic regime.},\\n bibtype = {article},\\n author = {Zhao, Q. and Liu, Y. and Yuan, X. and Chitambar, E. and Winter, A.},\\n doi = {10.1109/TIT.2019.2911102},\\n journal = {IEEE Transactions on Information Theory},\\n number = {10}\\n}\",\"author_short\":[\"Zhao,  Q.\",\"Liu,  Y.\",\"Yuan,  X.\",\"Chitambar,  E.\",\"Winter,  A.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"zhao-liu-yuan-chitambar-winter-oneshotcoherencedistillationtowardscompletingthepicture-2019\",\"role\":\"author\",\"urls\":{},\"keyword\":[\"Quantum coherence\",\"coherence distillation\",\"one-shot\",\"quantum resource theory\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":3,\"html\":\"\"},{\"title\":\"One-Shot Coherence Dilution\",\"type\":\"article\",\"year\":\"2018\",\"volume\":\"120\",\"id\":\"098aadac-771d-306d-99af-fd57ec84d625\",\"created\":\"2020-08-20T19:55:40.516Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.516Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2018 American Physical Society. Manipulation and quantification of quantum resources are fundamental problems in quantum physics. In the asymptotic limit, coherence distillation and dilution have been proposed by manipulating infinite identical copies of states. In the nonasymptotic setting, finite data-size effects emerge, and the practically relevant problem of coherence manipulation using finite resources has been left open. This Letter establishes the one-shot theory of coherence dilution, which involves converting maximally coherent states into an arbitrary quantum state using maximally incoherent operations, dephasing-covariant incoherent operations, incoherent operations, or strictly incoherent operations. We introduce several coherence monotones with concrete operational interpretations that estimate the one-shot coherence cost - the minimum amount of maximally coherent states needed for faithful coherence dilution. Furthermore, we derive the asymptotic coherence dilution results with maximally incoherent operations, incoherent operations, and strictly incoherent operations as special cases. Our result can be applied in the analyses of quantum information processing tasks that exploit coherence as resources, such as quantum key distribution and random number generation.\",\"bibtype\":\"article\",\"author\":\"Zhao, Q. and Liu, Y. and Yuan, X. and Chitambar, E. and Ma, X.\",\"doi\":\"10.1103/PhysRevLett.120.070403\",\"journal\":\"Physical Review Letters\",\"number\":\"7\",\"bibtex\":\"@article{\\n title = {One-Shot Coherence Dilution},\\n type = {article},\\n year = {2018},\\n volume = {120},\\n id = {098aadac-771d-306d-99af-fd57ec84d625},\\n created = {2020-08-20T19:55:40.516Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.516Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2018 American Physical Society. Manipulation and quantification of quantum resources are fundamental problems in quantum physics. In the asymptotic limit, coherence distillation and dilution have been proposed by manipulating infinite identical copies of states. In the nonasymptotic setting, finite data-size effects emerge, and the practically relevant problem of coherence manipulation using finite resources has been left open. This Letter establishes the one-shot theory of coherence dilution, which involves converting maximally coherent states into an arbitrary quantum state using maximally incoherent operations, dephasing-covariant incoherent operations, incoherent operations, or strictly incoherent operations. We introduce several coherence monotones with concrete operational interpretations that estimate the one-shot coherence cost - the minimum amount of maximally coherent states needed for faithful coherence dilution. Furthermore, we derive the asymptotic coherence dilution results with maximally incoherent operations, incoherent operations, and strictly incoherent operations as special cases. Our result can be applied in the analyses of quantum information processing tasks that exploit coherence as resources, such as quantum key distribution and random number generation.},\\n bibtype = {article},\\n author = {Zhao, Q. and Liu, Y. and Yuan, X. and Chitambar, E. and Ma, X.},\\n doi = {10.1103/PhysRevLett.120.070403},\\n journal = {Physical Review Letters},\\n number = {7}\\n}\",\"author_short\":[\"Zhao,  Q.\",\"Liu,  Y.\",\"Yuan,  X.\",\"Chitambar,  E.\",\"Ma,  X.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"zhao-liu-yuan-chitambar-ma-oneshotcoherencedilution-2018\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":2,\"html\":\"\"},{\"title\":\"Everything You Always Wanted to Know About LOCC (ButWere Afraid to Ask)\",\"type\":\"article\",\"year\":\"2014\",\"volume\":\"328\",\"id\":\"893a4a8b-b751-3122-ba65-52cbe6748e39\",\"created\":\"2020-08-20T19:55:40.559Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.559Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2014, Springer-Verlag Berlin Heidelberg. In this paper we study the subset of generalized quantum measurements on finite dimensional systems known as local operations and classical communication (LOCC). While LOCC emerges as the natural class of operations in many important quantum information tasks, its mathematical structure is complex and difficult to characterize. Here we provide a precise description of LOCC and related operational classes in terms of quantum instruments. Our formalism captures both finite round protocols as well as those that utilize an unbounded number of communication rounds.While the set of LOCC is not topologically closed, we show that finite round LOCC constitutes a compact subset of quantum operations. Additionally we show the existence of an open ball around the completely depolarizing map that consists entirely of LOCC implementable maps. Finally, we demonstrate a two-qubit map whose action can be approached arbitrarily close using LOCC, but nevertheless cannot be implemented perfectly.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Leung, D. and Mančinska, L. and Ozols, M. and Winter, A.\",\"doi\":\"10.1007/s00220-014-1953-9\",\"journal\":\"Communications in Mathematical Physics\",\"number\":\"1\",\"bibtex\":\"@article{\\n title = {Everything You Always Wanted to Know About LOCC (ButWere Afraid to Ask)},\\n type = {article},\\n year = {2014},\\n volume = {328},\\n id = {893a4a8b-b751-3122-ba65-52cbe6748e39},\\n created = {2020-08-20T19:55:40.559Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.559Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2014, Springer-Verlag Berlin Heidelberg. In this paper we study the subset of generalized quantum measurements on finite dimensional systems known as local operations and classical communication (LOCC). While LOCC emerges as the natural class of operations in many important quantum information tasks, its mathematical structure is complex and difficult to characterize. Here we provide a precise description of LOCC and related operational classes in terms of quantum instruments. Our formalism captures both finite round protocols as well as those that utilize an unbounded number of communication rounds.While the set of LOCC is not topologically closed, we show that finite round LOCC constitutes a compact subset of quantum operations. Additionally we show the existence of an open ball around the completely depolarizing map that consists entirely of LOCC implementable maps. Finally, we demonstrate a two-qubit map whose action can be approached arbitrarily close using LOCC, but nevertheless cannot be implemented perfectly.},\\n bibtype = {article},\\n author = {Chitambar, E. and Leung, D. and Mančinska, L. and Ozols, M. and Winter, A.},\\n doi = {10.1007/s00220-014-1953-9},\\n journal = {Communications in Mathematical Physics},\\n number = {1}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Leung,  D.\",\"Mančinska,  L.\",\"Ozols,  M.\",\"Winter,  A.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-leung-maninska-ozols-winter-everythingyoualwayswantedtoknowaboutloccbutwereafraidtoask-2014\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":2,\"html\":\"\"},{\"title\":\"Tensor rank and stochastic entanglement catalysis for multipartite pure states\",\"type\":\"article\",\"year\":\"2010\",\"volume\":\"105\",\"id\":\"48b80676-6ee1-3853-8a94-4018298f4624\",\"created\":\"2020-08-20T19:55:40.562Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.562Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"The tensor rank (also known as generalized Schmidt rank) of multipartite pure states plays an important role in the study of entanglement classifications and transformations. We employ powerful tools from the theory of homogeneous polynomials to investigate the tensor rank of symmetric states such as the tripartite state |W3=1√3(|100+|010+|001) and its N-partite generalization |WN. Previous tensor rank estimates are dramatically improved and we show that (i) three copies of |W3 have a rank of either 15 or 16, (ii) two copies of |WN have a rank of 3N-2, and (iii) n copies of |WN have a rank of O(N). A remarkable consequence of these results is that certain multipartite transformations, impossible even probabilistically, can become possible when performed in multiple-copy bunches or when assisted by some catalyzing state. This effect is impossible for bipartite pure states. © 2010 The American Physical Society.\",\"bibtype\":\"article\",\"author\":\"Chen, L. and Chitambar, E. and Duan, R. and Ji, Z. and Winter, A.\",\"doi\":\"10.1103/PhysRevLett.105.200501\",\"journal\":\"Physical Review Letters\",\"number\":\"20\",\"bibtex\":\"@article{\\n title = {Tensor rank and stochastic entanglement catalysis for multipartite pure states},\\n type = {article},\\n year = {2010},\\n volume = {105},\\n id = {48b80676-6ee1-3853-8a94-4018298f4624},\\n created = {2020-08-20T19:55:40.562Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.562Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {The tensor rank (also known as generalized Schmidt rank) of multipartite pure states plays an important role in the study of entanglement classifications and transformations. We employ powerful tools from the theory of homogeneous polynomials to investigate the tensor rank of symmetric states such as the tripartite state |W3=1√3(|100+|010+|001) and its N-partite generalization |WN. Previous tensor rank estimates are dramatically improved and we show that (i) three copies of |W3 have a rank of either 15 or 16, (ii) two copies of |WN have a rank of 3N-2, and (iii) n copies of |WN have a rank of O(N). A remarkable consequence of these results is that certain multipartite transformations, impossible even probabilistically, can become possible when performed in multiple-copy bunches or when assisted by some catalyzing state. This effect is impossible for bipartite pure states. © 2010 The American Physical Society.},\\n bibtype = {article},\\n author = {Chen, L. and Chitambar, E. and Duan, R. and Ji, Z. and Winter, A.},\\n doi = {10.1103/PhysRevLett.105.200501},\\n journal = {Physical Review Letters},\\n number = {20}\\n}\",\"author_short\":[\"Chen,  L.\",\"Chitambar,  E.\",\"Duan,  R.\",\"Ji,  Z.\",\"Winter,  A.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chen-chitambar-duan-ji-winter-tensorrankandstochasticentanglementcatalysisformultipartitepurestates-2010\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Loss-tolerant quantum secure positioning with weak laser sources\",\"type\":\"article\",\"year\":\"2016\",\"volume\":\"94\",\"id\":\"3ec9537c-2c12-34c4-a600-3131eea4ffb4\",\"created\":\"2020-08-20T19:55:40.601Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.601Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2016 American Physical Society. Quantum position verification (QPV) is the art of verifying the geographical location of an untrusted party. Recently, it has been shown that the widely studied Bennett & Brassard 1984 (BB84) QPV protocol is insecure after the 3 dB loss point assuming local operations and classical communication (LOCC) adversaries. Here, we propose a time-reversed entanglement swapping QPV protocol (based on measurement-device-independent quantum cryptography) that is highly robust against quantum channel loss. First, assuming ideal qubit sources, we show that the protocol is secure against LOCC adversaries for any quantum channel loss, thereby overcoming the 3 dB loss limit. Then, we analyze the security of the protocol in a more practical setting involving weak laser sources and linear optics. In this setting, we find that the security only degrades by an additive constant and the protocol is able to verify positions up to 47 dB channel loss.\",\"bibtype\":\"article\",\"author\":\"Lim, C.C.W. and Xu, F. and Siopsis, G. and Chitambar, E. and Evans, P.G. and Qi, B.\",\"doi\":\"10.1103/PhysRevA.94.032315\",\"journal\":\"Physical Review A\",\"number\":\"3\",\"bibtex\":\"@article{\\n title = {Loss-tolerant quantum secure positioning with weak laser sources},\\n type = {article},\\n year = {2016},\\n volume = {94},\\n id = {3ec9537c-2c12-34c4-a600-3131eea4ffb4},\\n created = {2020-08-20T19:55:40.601Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.601Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2016 American Physical Society. Quantum position verification (QPV) is the art of verifying the geographical location of an untrusted party. Recently, it has been shown that the widely studied Bennett & Brassard 1984 (BB84) QPV protocol is insecure after the 3 dB loss point assuming local operations and classical communication (LOCC) adversaries. Here, we propose a time-reversed entanglement swapping QPV protocol (based on measurement-device-independent quantum cryptography) that is highly robust against quantum channel loss. First, assuming ideal qubit sources, we show that the protocol is secure against LOCC adversaries for any quantum channel loss, thereby overcoming the 3 dB loss limit. Then, we analyze the security of the protocol in a more practical setting involving weak laser sources and linear optics. In this setting, we find that the security only degrades by an additive constant and the protocol is able to verify positions up to 47 dB channel loss.},\\n bibtype = {article},\\n author = {Lim, C.C.W. and Xu, F. and Siopsis, G. and Chitambar, E. and Evans, P.G. and Qi, B.},\\n doi = {10.1103/PhysRevA.94.032315},\\n journal = {Physical Review A},\\n number = {3}\\n}\",\"author_short\":[\"Lim,  C.\",\"Xu,  F.\",\"Siopsis,  G.\",\"Chitambar,  E.\",\"Evans,  P.\",\"Qi,  B.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"lim-xu-siopsis-chitambar-evans-qi-losstolerantquantumsecurepositioningwithweaklasersources-2016\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Entanglement and Coherence in Quantum State Merging\",\"type\":\"article\",\"year\":\"2016\",\"volume\":\"116\",\"id\":\"a8d15d70-122f-3796-9f10-5b650bc7e4b8\",\"created\":\"2020-08-20T19:55:40.608Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.608Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2016 American Physical Society. Understanding the resource consumption in distributed scenarios is one of the main goals of quantum information theory. A prominent example for such a scenario is the task of quantum state merging, where two parties aim to merge their tripartite quantum state parts. In standard quantum state merging, entanglement is considered to be an expensive resource, while local quantum operations can be performed at no additional cost. However, recent developments show that some local operations could be more expensive than others: it is reasonable to distinguish between local incoherent operations and local operations which can create coherence. This idea leads us to the task of incoherent quantum state merging, where one of the parties has free access to local incoherent operations only. In this case the resources of the process are quantified by pairs of entanglement and coherence. Here, we develop tools for studying this process and apply them to several relevant scenarios. While quantum state merging can lead to a gain of entanglement, our results imply that no merging procedure can gain entanglement and coherence at the same time. We also provide a general lower bound on the entanglement-coherence sum and show that the bound is tight for all pure states. Our results also lead to an incoherent version of Schumacher compression: in this case the compression rate is equal to the von Neumann entropy of the diagonal elements of the corresponding quantum state.\",\"bibtype\":\"article\",\"author\":\"Streltsov, A. and Chitambar, E. and Rana, S. and Bera, M.N. and Winter, A. and Lewenstein, M.\",\"doi\":\"10.1103/PhysRevLett.116.240405\",\"journal\":\"Physical Review Letters\",\"number\":\"24\",\"bibtex\":\"@article{\\n title = {Entanglement and Coherence in Quantum State Merging},\\n type = {article},\\n year = {2016},\\n volume = {116},\\n id = {a8d15d70-122f-3796-9f10-5b650bc7e4b8},\\n created = {2020-08-20T19:55:40.608Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.608Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2016 American Physical Society. Understanding the resource consumption in distributed scenarios is one of the main goals of quantum information theory. A prominent example for such a scenario is the task of quantum state merging, where two parties aim to merge their tripartite quantum state parts. In standard quantum state merging, entanglement is considered to be an expensive resource, while local quantum operations can be performed at no additional cost. However, recent developments show that some local operations could be more expensive than others: it is reasonable to distinguish between local incoherent operations and local operations which can create coherence. This idea leads us to the task of incoherent quantum state merging, where one of the parties has free access to local incoherent operations only. In this case the resources of the process are quantified by pairs of entanglement and coherence. Here, we develop tools for studying this process and apply them to several relevant scenarios. While quantum state merging can lead to a gain of entanglement, our results imply that no merging procedure can gain entanglement and coherence at the same time. We also provide a general lower bound on the entanglement-coherence sum and show that the bound is tight for all pure states. Our results also lead to an incoherent version of Schumacher compression: in this case the compression rate is equal to the von Neumann entropy of the diagonal elements of the corresponding quantum state.},\\n bibtype = {article},\\n author = {Streltsov, A. and Chitambar, E. and Rana, S. and Bera, M.N. and Winter, A. and Lewenstein, M.},\\n doi = {10.1103/PhysRevLett.116.240405},\\n journal = {Physical Review Letters},\\n number = {24}\\n}\",\"author_short\":[\"Streltsov,  A.\",\"Chitambar,  E.\",\"Rana,  S.\",\"Bera,  M.\",\"Winter,  A.\",\"Lewenstein,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"streltsov-chitambar-rana-bera-winter-lewenstein-entanglementandcoherenceinquantumstatemerging-2016\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Assisted Distillation of Quantum Coherence\",\"type\":\"article\",\"year\":\"2016\",\"volume\":\"116\",\"id\":\"b5a2dda9-8007-3be0-8d57-ae0a1d4b785f\",\"created\":\"2020-08-20T19:55:40.655Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.655Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2016 American Physical Society. We introduce and study the task of assisted coherence distillation. This task arises naturally in bipartite systems where both parties work together to generate the maximal possible coherence on one of the subsystems. Only incoherent operations are allowed on the target system, while general local quantum operations are permitted on the other; this is an operational paradigm that we call local quantum-incoherent operations and classical communication. We show that the asymptotic rate of assisted coherence distillation for pure states is equal to the coherence of assistance, an analog of the entanglement of assistance, whose properties we characterize. Our findings imply a novel interpretation of the von Neumann entropy: it quantifies the maximum amount of extra quantum coherence a system can gain when receiving assistance from a collaborative party. Our results are generalized to coherence localization in a multipartite setting and possible applications are discussed.\",\"bibtype\":\"article\",\"author\":\"Chitambar, E. and Streltsov, A. and Rana, S. and Bera, M.N. and Adesso, G. and Lewenstein, M.\",\"doi\":\"10.1103/PhysRevLett.116.070402\",\"journal\":\"Physical Review Letters\",\"number\":\"7\",\"bibtex\":\"@article{\\n title = {Assisted Distillation of Quantum Coherence},\\n type = {article},\\n year = {2016},\\n volume = {116},\\n id = {b5a2dda9-8007-3be0-8d57-ae0a1d4b785f},\\n created = {2020-08-20T19:55:40.655Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.655Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2016 American Physical Society. We introduce and study the task of assisted coherence distillation. This task arises naturally in bipartite systems where both parties work together to generate the maximal possible coherence on one of the subsystems. Only incoherent operations are allowed on the target system, while general local quantum operations are permitted on the other; this is an operational paradigm that we call local quantum-incoherent operations and classical communication. We show that the asymptotic rate of assisted coherence distillation for pure states is equal to the coherence of assistance, an analog of the entanglement of assistance, whose properties we characterize. Our findings imply a novel interpretation of the von Neumann entropy: it quantifies the maximum amount of extra quantum coherence a system can gain when receiving assistance from a collaborative party. Our results are generalized to coherence localization in a multipartite setting and possible applications are discussed.},\\n bibtype = {article},\\n author = {Chitambar, E. and Streltsov, A. and Rana, S. and Bera, M.N. and Adesso, G. and Lewenstein, M.},\\n doi = {10.1103/PhysRevLett.116.070402},\\n journal = {Physical Review Letters},\\n number = {7}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Streltsov,  A.\",\"Rana,  S.\",\"Bera,  M.\",\"Adesso,  G.\",\"Lewenstein,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-streltsov-rana-bera-adesso-lewenstein-assisteddistillationofquantumcoherence-2016\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":2,\"html\":\"\"},{\"title\":\"Free-space reconfigurable quantum key distribution network\",\"type\":\"inproceedings\",\"year\":\"2016\",\"id\":\"958d0a84-e026-34d2-8685-758e8b7313e9\",\"created\":\"2020-08-20T19:55:40.664Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-08-20T19:55:40.664Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2015 IEEE. We propose a free-space reconfigurable quantum key distribution (QKD) network to secure communication among mobile users. Depends on the trustworthiness of the network relay, the users can implement either the highly secure measurement-device-independent QKD, or the highly efficient decoy state BB84 QKD. Based on the same quantum infrastructure, we also propose a loss tolerant quantum position verification scheme, which could allow the QKD users to initiate the QKD process without relying on pre-shared key.\",\"bibtype\":\"inproceedings\",\"author\":\"Qi, B. and Lo, H.-K. and Lim, C.C.W. and Siopsis, G. and Chitambar, E.A. and Pooser, R. and Evans, P.G. and Grice, W.\",\"doi\":\"10.1109/ICSOS.2015.7425063\",\"booktitle\":\"2015 IEEE International Conference on Space Optical Systems and Applications, ICSOS 2015\",\"bibtex\":\"@inproceedings{\\n title = {Free-space reconfigurable quantum key distribution network},\\n type = {inproceedings},\\n year = {2016},\\n id = {958d0a84-e026-34d2-8685-758e8b7313e9},\\n created = {2020-08-20T19:55:40.664Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-08-20T19:55:40.664Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2015 IEEE. We propose a free-space reconfigurable quantum key distribution (QKD) network to secure communication among mobile users. Depends on the trustworthiness of the network relay, the users can implement either the highly secure measurement-device-independent QKD, or the highly efficient decoy state BB84 QKD. Based on the same quantum infrastructure, we also propose a loss tolerant quantum position verification scheme, which could allow the QKD users to initiate the QKD process without relying on pre-shared key.},\\n bibtype = {inproceedings},\\n author = {Qi, B. and Lo, H.-K. and Lim, C.C.W. and Siopsis, G. and Chitambar, E.A. and Pooser, R. and Evans, P.G. and Grice, W.},\\n doi = {10.1109/ICSOS.2015.7425063},\\n booktitle = {2015 IEEE International Conference on Space Optical Systems and Applications, ICSOS 2015}\\n}\",\"author_short\":[\"Qi,  B.\",\"Lo,  H.\",\"Lim,  C.\",\"Siopsis,  G.\",\"Chitambar,  E.\",\"Pooser,  R.\",\"Evans,  P.\",\"Grice,  W.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"qi-lo-lim-siopsis-chitambar-pooser-evans-grice-freespacereconfigurablequantumkeydistributionnetwork-2016\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Entanglement-breaking superchannels\",\"type\":\"article\",\"year\":\"2020\",\"volume\":\"4\",\"id\":\"71f44b56-76d4-3560-bf91-8fc303374b77\",\"created\":\"2020-10-12T23:59:00.000Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-10-15T07:26:13.634Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"© 2020 Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften. All rights reserved. In this paper we initiate the study of entanglement-breaking (EB) superchannels. These are processes that always yield separable maps when acting on one side of a bipartite completely positive (CP) map. EB superchannels are a generalization of the well-known EB channels. We give several equivalent characterizations of EB supermaps and superchannels. Unlike its channel counterpart, we find that not every EB superchannel can be implemented as a measure-and-prepare superchannel. We also demonstrate that many EB superchannels can be superactivated, in the sense that they can output non-separable channels when wired in series. We then introduce the notions of CPTP- and CP-complete images of a superchannel, which capture deterministic and probabilistic channel convertibility, respectively. This allows us to characterize the power of EB superchannels for generating CP maps in different scenarios, and it reveals some fundamental differences between channels and superchannels. Finally, we relax the definition of separable channels to include (p, q)-non-entangling channels, which are bipartite channels that cannot generate entanglement using p- and q-dimensional ancillary systems. By introducing and investigating k-EB maps, we construct examples of (p, q)-EB superchannels that are not fully entanglement breaking. Partial results on the characterization of (p, q)-EB superchannels are also provided.\",\"bibtype\":\"article\",\"author\":\"Chen, S. and Chitambar, E.\",\"doi\":\"10.22331/q-2020-07-16-299\",\"journal\":\"Quantum\",\"bibtex\":\"@article{\\n title = {Entanglement-breaking superchannels},\\n type = {article},\\n year = {2020},\\n volume = {4},\\n id = {71f44b56-76d4-3560-bf91-8fc303374b77},\\n created = {2020-10-12T23:59:00.000Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-10-15T07:26:13.634Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {© 2020 Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften. All rights reserved. In this paper we initiate the study of entanglement-breaking (EB) superchannels. These are processes that always yield separable maps when acting on one side of a bipartite completely positive (CP) map. EB superchannels are a generalization of the well-known EB channels. We give several equivalent characterizations of EB supermaps and superchannels. Unlike its channel counterpart, we find that not every EB superchannel can be implemented as a measure-and-prepare superchannel. We also demonstrate that many EB superchannels can be superactivated, in the sense that they can output non-separable channels when wired in series. We then introduce the notions of CPTP- and CP-complete images of a superchannel, which capture deterministic and probabilistic channel convertibility, respectively. This allows us to characterize the power of EB superchannels for generating CP maps in different scenarios, and it reveals some fundamental differences between channels and superchannels. Finally, we relax the definition of separable channels to include (p, q)-non-entangling channels, which are bipartite channels that cannot generate entanglement using p- and q-dimensional ancillary systems. By introducing and investigating k-EB maps, we construct examples of (p, q)-EB superchannels that are not fully entanglement breaking. Partial results on the characterization of (p, q)-EB superchannels are also provided.},\\n bibtype = {article},\\n author = {Chen, S. and Chitambar, E.},\\n doi = {10.22331/q-2020-07-16-299},\\n journal = {Quantum}\\n}\",\"author_short\":[\"Chen,  S.\",\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chen-chitambar-entanglementbreakingsuperchannels-2020\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":1,\"html\":\"\"},{\"title\":\"One-shot coherence dilution\",\"type\":\"misc\",\"year\":\"2017\",\"source\":\"arXiv\",\"id\":\"6fc95380-ce40-3e52-8c7e-d900dcbf9d05\",\"created\":\"2020-10-27T23:59:00.000Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-10-30T08:41:11.297Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Copyright © 2017, arXiv, All rights reserved. Manipulation and quantification of quantum resources are fundamental problems in quantum physics. In the asymptotic limit, coherence distillation and dilution have been proposed by manipulating infinite identical copies of states. In the nonasymptotic setting, finite data-size effects emerge, and the practically relevant problem of coherence manipulation using finite resources has been left open. This Letter establishes the one-shot theory of coherence dilution, which involves converting maximally coherent states into an arbitrary quantum state using maximally incoherent operations, dephasing-covariant incoherent operations, incoherent operations, or strictly incoherent operations. We introduce several coherence monotones with concrete operational interpretations that estimate the one-shot coherence cost-the minimum amount of maximally coherent states needed for faithful coherence dilution. Furthermore, we derive the asymptotic coherence dilution results with maximally incoherent operations, incoherent operations, and strictly incoherent operations as special cases. Our result can be applied in the analyses of quantum information processing tasks that exploit coherence as resources, such as quantum key distribution and random number generation.\",\"bibtype\":\"misc\",\"author\":\"Zhao, Q. and Liu, Y. and Yuan, X. and Chitambar, E. and Ma, X.\",\"bibtex\":\"@misc{\\n title = {One-shot coherence dilution},\\n type = {misc},\\n year = {2017},\\n source = {arXiv},\\n id = {6fc95380-ce40-3e52-8c7e-d900dcbf9d05},\\n created = {2020-10-27T23:59:00.000Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-10-30T08:41:11.297Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Copyright © 2017, arXiv, All rights reserved. Manipulation and quantification of quantum resources are fundamental problems in quantum physics. In the asymptotic limit, coherence distillation and dilution have been proposed by manipulating infinite identical copies of states. In the nonasymptotic setting, finite data-size effects emerge, and the practically relevant problem of coherence manipulation using finite resources has been left open. This Letter establishes the one-shot theory of coherence dilution, which involves converting maximally coherent states into an arbitrary quantum state using maximally incoherent operations, dephasing-covariant incoherent operations, incoherent operations, or strictly incoherent operations. We introduce several coherence monotones with concrete operational interpretations that estimate the one-shot coherence cost-the minimum amount of maximally coherent states needed for faithful coherence dilution. Furthermore, we derive the asymptotic coherence dilution results with maximally incoherent operations, incoherent operations, and strictly incoherent operations as special cases. Our result can be applied in the analyses of quantum information processing tasks that exploit coherence as resources, such as quantum key distribution and random number generation.},\\n bibtype = {misc},\\n author = {Zhao, Q. and Liu, Y. and Yuan, X. and Chitambar, E. and Ma, X.}\\n}\",\"author_short\":[\"Zhao,  Q.\",\"Liu,  Y.\",\"Yuan,  X.\",\"Chitambar,  E.\",\"Ma,  X.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"zhao-liu-yuan-chitambar-ma-oneshotcoherencedilution-2017\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Entanglement manipulation and distillability beyond LOCC\",\"type\":\"misc\",\"year\":\"2017\",\"source\":\"arXiv\",\"id\":\"a3a4a68b-b654-38c2-9bc7-c197ffe03a00\",\"created\":\"2020-10-27T23:59:00.000Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-10-31T01:16:47.915Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Copyright © 2017, arXiv, All rights reserved. When a quantum system is distributed to spatially separated parties, it is natural to consider how the system evolves when the parties perform local quantum operations with classical communication (LOCC). However, the structure of LOCC channels is exceedingly complex leaving many important physical problems unsolved. In this paper we consider generalized resource theories of entanglement based on different relaxations to the class of LOCC. The behavior of various entanglement measures is studied under non-entangling channels, as well as the newly introduced classes of dually non-entangling and PPT-preserving channels. In an effort to better understand the nature of LOCC bound entanglement, we study the problem of entanglement distillation in these generalized resource theories. We first show that unlike LOCC, general non-entangling maps can be superactivated, in the sense that two copies of the same non-entangling map can nevertheless be entangling. On the single-copy level, we demonstrate that every NPT entangled state can be converted into an LOCC-distillable state using channels that are both dually non-entangling and having a PPT Choi representation and that every state can be converted into an LOCC-distillable state using operations belonging to any family of polytopes that approximate LOCC. We then turn to the stochastic convertibility of multipartite pure states and show that any two states can be interconverted by any polytope approximation to the set of separable channels. Finally, as an analog to k-positive maps, we introduce and analyze the set of k-non-entangling channels.\",\"bibtype\":\"misc\",\"author\":\"Chitambar, E. and De Vicente, J.I. and Girard, M.W. and Gour, G.\",\"bibtex\":\"@misc{\\n title = {Entanglement manipulation and distillability beyond LOCC},\\n type = {misc},\\n year = {2017},\\n source = {arXiv},\\n id = {a3a4a68b-b654-38c2-9bc7-c197ffe03a00},\\n created = {2020-10-27T23:59:00.000Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-10-31T01:16:47.915Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Copyright © 2017, arXiv, All rights reserved. When a quantum system is distributed to spatially separated parties, it is natural to consider how the system evolves when the parties perform local quantum operations with classical communication (LOCC). However, the structure of LOCC channels is exceedingly complex leaving many important physical problems unsolved. In this paper we consider generalized resource theories of entanglement based on different relaxations to the class of LOCC. The behavior of various entanglement measures is studied under non-entangling channels, as well as the newly introduced classes of dually non-entangling and PPT-preserving channels. In an effort to better understand the nature of LOCC bound entanglement, we study the problem of entanglement distillation in these generalized resource theories. We first show that unlike LOCC, general non-entangling maps can be superactivated, in the sense that two copies of the same non-entangling map can nevertheless be entangling. On the single-copy level, we demonstrate that every NPT entangled state can be converted into an LOCC-distillable state using channels that are both dually non-entangling and having a PPT Choi representation and that every state can be converted into an LOCC-distillable state using operations belonging to any family of polytopes that approximate LOCC. We then turn to the stochastic convertibility of multipartite pure states and show that any two states can be interconverted by any polytope approximation to the set of separable channels. Finally, as an analog to k-positive maps, we introduce and analyze the set of k-non-entangling channels.},\\n bibtype = {misc},\\n author = {Chitambar, E. and De Vicente, J.I. and Girard, M.W. and Gour, G.}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"De Vicente,  J.\",\"Girard,  M.\",\"Gour,  G.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-devicente-girard-gour-entanglementmanipulationanddistillabilitybeyondlocc-2017\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"One-shot distillation in a general resource theory\",\"type\":\"misc\",\"year\":\"2019\",\"source\":\"arXiv\",\"id\":\"4489a828-41da-3770-a4a8-5350ff4f0dce\",\"created\":\"2020-11-03T23:59:00.000Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-11-04T16:59:45.444Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Copyright © 2019, arXiv, All rights reserved. We present a general framework of a quantum resource theory based on the assumption of a) convexity and b) that the overlap of free states with maximally resourceful state is bounded. Using this structure, we derive bounds on the one-shot distillation rate for such a resource theory, thereby reproducing known bounds in coherence and entanglement. We use the free robustness and introduce a function Gmin(ρ) related to overlap between ρ and the set of free states to express our bounds. To deal with resource theories where the free robustness in not finite we introduce the notion of imperfect free operations which we call ϵ-resource generating operations and generalize the free robustness to ϵ-free robustness. We construct an ϵ-resource generating map that achieves pure state transformations in the theory and derive the conditions for such a transformation to exist in terms of the ϵ-free robustness.\",\"bibtype\":\"misc\",\"author\":\"Vijayan, M.K. and Chitambar, E. and Hsieh, M.-H.\",\"bibtex\":\"@misc{\\n title = {One-shot distillation in a general resource theory},\\n type = {misc},\\n year = {2019},\\n source = {arXiv},\\n id = {4489a828-41da-3770-a4a8-5350ff4f0dce},\\n created = {2020-11-03T23:59:00.000Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-11-04T16:59:45.444Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Copyright © 2019, arXiv, All rights reserved. We present a general framework of a quantum resource theory based on the assumption of a) convexity and b) that the overlap of free states with maximally resourceful state is bounded. Using this structure, we derive bounds on the one-shot distillation rate for such a resource theory, thereby reproducing known bounds in coherence and entanglement. We use the free robustness and introduce a function Gmin(ρ) related to overlap between ρ and the set of free states to express our bounds. To deal with resource theories where the free robustness in not finite we introduce the notion of imperfect free operations which we call ϵ-resource generating operations and generalize the free robustness to ϵ-free robustness. We construct an ϵ-resource generating map that achieves pure state transformations in the theory and derive the conditions for such a transformation to exist in terms of the ϵ-free robustness.},\\n bibtype = {misc},\\n author = {Vijayan, M.K. and Chitambar, E. and Hsieh, M.-H.}\\n}\",\"author_short\":[\"Vijayan,  M.\",\"Chitambar,  E.\",\"Hsieh,  M.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"vijayan-chitambar-hsieh-oneshotdistillationinageneralresourcetheory-2019\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Dephasing-Covariant Operations Enable Asymptotic Reversibility of Quantum Resources\",\"type\":\"misc\",\"year\":\"2017\",\"source\":\"arXiv\",\"id\":\"8ac819e4-af60-31cb-b05e-a9d21cb78dce\",\"created\":\"2020-11-03T23:59:00.000Z\",\"file_attached\":false,\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2020-11-05T01:35:55.742Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Copyright © 2017, arXiv, All rights reserved. We study the power of dephasing-covariant operations in the resource theories of coherence and entanglement. These are quantum operations whose actions commute with a projective measurement. In the resource theory of coherence, we find that any two states are asymptotically interconvertible under dephasing-covariant operations. This provides a rare example of a resource theory in which asymptotic reversibility can be attained without needing the maximal set of resource non-generating operations. When extended to the resource theory of entanglement, the resultant operations share similarities with LOCC, such as prohibiting the increase of all Rényi α-entropies of entanglement under pure state transformations. However, we show these operations are still strong enough to enable asymptotic reversibility between any two maximally correlated mixed states, even in the multipartite setting.\",\"bibtype\":\"misc\",\"author\":\"Chitambar, E.\",\"bibtex\":\"@misc{\\n title = {Dephasing-Covariant Operations Enable Asymptotic Reversibility of Quantum Resources},\\n type = {misc},\\n year = {2017},\\n source = {arXiv},\\n id = {8ac819e4-af60-31cb-b05e-a9d21cb78dce},\\n created = {2020-11-03T23:59:00.000Z},\\n file_attached = {false},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2020-11-05T01:35:55.742Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Copyright © 2017, arXiv, All rights reserved. We study the power of dephasing-covariant operations in the resource theories of coherence and entanglement. These are quantum operations whose actions commute with a projective measurement. In the resource theory of coherence, we find that any two states are asymptotically interconvertible under dephasing-covariant operations. This provides a rare example of a resource theory in which asymptotic reversibility can be attained without needing the maximal set of resource non-generating operations. When extended to the resource theory of entanglement, the resultant operations share similarities with LOCC, such as prohibiting the increase of all Rényi α-entropies of entanglement under pure state transformations. However, we show these operations are still strong enough to enable asymptotic reversibility between any two maximally correlated mixed states, even in the multipartite setting.},\\n bibtype = {misc},\\n author = {Chitambar, E.}\\n}\",\"author_short\":[\"Chitambar,  E.\"],\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-dephasingcovariantoperationsenableasymptoticreversibilityofquantumresources-2017\",\"role\":\"author\",\"urls\":{},\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"On the Duality of Teleportation and Dense Coding\",\"type\":\"article\",\"year\":\"2024\",\"pages\":\"3529-3537\",\"volume\":\"70\",\"websites\":\"https://ieeexplore.ieee.org/document/10315956/\",\"month\":\"5\",\"publisher\":\"Institute of Electrical and Electronics Engineers Inc.\",\"id\":\"0c5f12d2-17dc-3ba3-a6da-2b7c3897488e\",\"created\":\"2025-04-11T19:50:02.491Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-13T16:53:53.779Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Quantum teleportation is a quantum communication primitive that allows a long-distance quantum channel to be built using pre-shared entanglement and one-way classical communication. However, the quality of the established channel crucially depends on the quality of the pre-shared entanglement. In this work, we revisit the problem of using noisy entanglement for the task of teleportation. We first show how this problem can be rephrased as a state discrimination problem. In this picture, a quantitative duality between teleportation and dense coding emerges in which every Alice-to-Bob teleportation protocol can be repurposed as a Bob-to-Alice dense coding protocol, and the quality of each protocol can be measured by the success probability in the same state discrimination problem. One of our main results provides a complete characterization of the states that offer no advantage in one-way teleportation protocols over classical states, thereby offering a new and intriguing perspective on the long-standing open problem of identifying such states. This also yields a new proof of the known fact that bound entangled states cannot exceed the classical teleportation threshold. Moreover, our established duality between teleportation and dense coding can be used to show that the exact same states are unable to provide a non-classical advantage for dense coding as well. We also discuss the duality from a communication capacity point of view, deriving upper and lower bounds on the accessible information of a dense coding protocol in terms of the fidelity of its associated teleportation protocol. A corollary of this discussion is a simple proof of the previously established fact that bound entangled states do not provide any advantage in dense coding.\",\"bibtype\":\"article\",\"author\":\"Chitambar, Eric and Leditzky, Felix\",\"doi\":\"10.1109/TIT.2023.3331821\",\"journal\":\"IEEE Transactions on Information Theory\",\"number\":\"5\",\"bibtex\":\"@article{\\n title = {On the Duality of Teleportation and Dense Coding},\\n type = {article},\\n year = {2024},\\n pages = {3529-3537},\\n volume = {70},\\n websites = {https://ieeexplore.ieee.org/document/10315956/},\\n month = {5},\\n publisher = {Institute of Electrical and Electronics Engineers Inc.},\\n id = {0c5f12d2-17dc-3ba3-a6da-2b7c3897488e},\\n created = {2025-04-11T19:50:02.491Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-13T16:53:53.779Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Quantum teleportation is a quantum communication primitive that allows a long-distance quantum channel to be built using pre-shared entanglement and one-way classical communication. However, the quality of the established channel crucially depends on the quality of the pre-shared entanglement. In this work, we revisit the problem of using noisy entanglement for the task of teleportation. We first show how this problem can be rephrased as a state discrimination problem. In this picture, a quantitative duality between teleportation and dense coding emerges in which every Alice-to-Bob teleportation protocol can be repurposed as a Bob-to-Alice dense coding protocol, and the quality of each protocol can be measured by the success probability in the same state discrimination problem. One of our main results provides a complete characterization of the states that offer no advantage in one-way teleportation protocols over classical states, thereby offering a new and intriguing perspective on the long-standing open problem of identifying such states. This also yields a new proof of the known fact that bound entangled states cannot exceed the classical teleportation threshold. Moreover, our established duality between teleportation and dense coding can be used to show that the exact same states are unable to provide a non-classical advantage for dense coding as well. We also discuss the duality from a communication capacity point of view, deriving upper and lower bounds on the accessible information of a dense coding protocol in terms of the fidelity of its associated teleportation protocol. A corollary of this discussion is a simple proof of the previously established fact that bound entangled states do not provide any advantage in dense coding.},\\n bibtype = {article},\\n author = {Chitambar, Eric and Leditzky, Felix},\\n doi = {10.1109/TIT.2023.3331821},\\n journal = {IEEE Transactions on Information Theory},\\n number = {5}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Leditzky,  F.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/03dd6130-0f22-7da7-7bc9-e067fc23b4ef/Chitambar_2024_On_the_Duality_of_Teleportation_and_Dense_C_1.pdf.pdf\",\"Website\":\"https://ieeexplore.ieee.org/document/10315956/\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-leditzky-onthedualityofteleportationanddensecoding-2024\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"The Communication Value of a Quantum Channel\",\"type\":\"inproceedings\",\"year\":\"2023\",\"keywords\":\"Quantum information science,quantum channels,quantum entanglement\",\"pages\":\"1660-1679\",\"volume\":\"69\",\"issue\":\"3\",\"month\":\"3\",\"publisher\":\"Institute of Electrical and Electronics Engineers Inc.\",\"day\":\"1\",\"id\":\"dae6743e-b456-39b8-99d3-ce430ef1797a\",\"created\":\"2025-04-11T19:50:02.576Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-11T19:50:57.786Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"There are various ways to quantify the communication capabilities of a quantum channel. In this work we introduce the communication value (cv) of quantum channel, which describes the optimal probability of guessing the channel input from its output. By connecting to prior work on zero-error channel simulation, we show that the cv and its entanglement-assisted variant also offer dual interpretations as the classical communication cost for perfectly simulating different aspects of a channel using non-signaling resources. Our study involves characterizing the communication value as a generalized conditional min-entropy over the cone of separable operators. Using this characterization, we evaluate the cv for all qubit channels and higher-dimensional channels with certain symmetries. We find that the any entanglement-breaking channel has multiplicative cv when used in parallel with any other channel; the same is shown to hold for Pauli channels and partially depolarizing channels. In contrast, the cv is found to be non-multiplicative for a subset of the well-known Werner-Holevo channels. A final component of this work investigates relaxations of the channel cv to other cones such as the set of operators having a positive partial transpose (PPT).\",\"bibtype\":\"inproceedings\",\"author\":\"Chitambar, Eric and George, Ian and Doolittle, Brian and Junge, Marius\",\"doi\":\"10.1109/TIT.2022.3218540\",\"booktitle\":\"IEEE Transactions on Information Theory\",\"bibtex\":\"@inproceedings{\\n title = {The Communication Value of a Quantum Channel},\\n type = {inproceedings},\\n year = {2023},\\n keywords = {Quantum information science,quantum channels,quantum entanglement},\\n pages = {1660-1679},\\n volume = {69},\\n issue = {3},\\n month = {3},\\n publisher = {Institute of Electrical and Electronics Engineers Inc.},\\n day = {1},\\n id = {dae6743e-b456-39b8-99d3-ce430ef1797a},\\n created = {2025-04-11T19:50:02.576Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-11T19:50:57.786Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {There are various ways to quantify the communication capabilities of a quantum channel. In this work we introduce the communication value (cv) of quantum channel, which describes the optimal probability of guessing the channel input from its output. By connecting to prior work on zero-error channel simulation, we show that the cv and its entanglement-assisted variant also offer dual interpretations as the classical communication cost for perfectly simulating different aspects of a channel using non-signaling resources. Our study involves characterizing the communication value as a generalized conditional min-entropy over the cone of separable operators. Using this characterization, we evaluate the cv for all qubit channels and higher-dimensional channels with certain symmetries. We find that the any entanglement-breaking channel has multiplicative cv when used in parallel with any other channel; the same is shown to hold for Pauli channels and partially depolarizing channels. In contrast, the cv is found to be non-multiplicative for a subset of the well-known Werner-Holevo channels. A final component of this work investigates relaxations of the channel cv to other cones such as the set of operators having a positive partial transpose (PPT).},\\n bibtype = {inproceedings},\\n author = {Chitambar, Eric and George, Ian and Doolittle, Brian and Junge, Marius},\\n doi = {10.1109/TIT.2022.3218540},\\n booktitle = {IEEE Transactions on Information Theory}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"George,  I.\",\"Doolittle,  B.\",\"Junge,  M.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4ee75966-1617-78b7-6791-3e955f33b61b/Chitambar_2023_The_Communication_Value_of_a_Quantum_Channel.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-george-doolittle-junge-thecommunicationvalueofaquantumchannel-2023\",\"role\":\"author\",\"keyword\":[\"Quantum information science\",\"quantum channels\",\"quantum entanglement\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Multipartite Nonlocality in Clifford Networks\",\"type\":\"article\",\"year\":\"2023\",\"volume\":\"130\",\"month\":\"6\",\"publisher\":\"American Physical Society\",\"day\":\"16\",\"id\":\"2cdf606b-7faa-3797-8a01-c41dde4a4f53\",\"created\":\"2025-04-11T23:19:47.123Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T17:35:10.944Z\",\"read\":\"true\",\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"We adopt a resource-theoretic framework to classify different types of quantum network nonlocality in terms of operational constraints placed on the network. One type of constraint limits the parties to perform local Clifford gates on pure stabilizer states, and we show that quantum network nonlocality cannot emerge in this setting. Yet, if the constraint is relaxed to allow for mixed stabilizer states, then network nonlocality can indeed be obtained. We additionally show that bipartite entanglement is sufficient for generating all forms of quantum network nonlocality when allowing for postselection, a property analogous to the universality of bipartite entanglement for generating all forms of multipartite entangled states.\",\"bibtype\":\"article\",\"author\":\"Gatto Lamas, Amanda and Chitambar, Eric\",\"doi\":\"10.1103/PhysRevLett.130.240802\",\"journal\":\"Physical Review Letters\",\"number\":\"24\",\"bibtex\":\"@article{\\n title = {Multipartite Nonlocality in Clifford Networks},\\n type = {article},\\n year = {2023},\\n volume = {130},\\n month = {6},\\n publisher = {American Physical Society},\\n day = {16},\\n id = {2cdf606b-7faa-3797-8a01-c41dde4a4f53},\\n created = {2025-04-11T23:19:47.123Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T17:35:10.944Z},\\n read = {true},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {We adopt a resource-theoretic framework to classify different types of quantum network nonlocality in terms of operational constraints placed on the network. One type of constraint limits the parties to perform local Clifford gates on pure stabilizer states, and we show that quantum network nonlocality cannot emerge in this setting. Yet, if the constraint is relaxed to allow for mixed stabilizer states, then network nonlocality can indeed be obtained. We additionally show that bipartite entanglement is sufficient for generating all forms of quantum network nonlocality when allowing for postselection, a property analogous to the universality of bipartite entanglement for generating all forms of multipartite entangled states.},\\n bibtype = {article},\\n author = {Gatto Lamas, Amanda and Chitambar, Eric},\\n doi = {10.1103/PhysRevLett.130.240802},\\n journal = {Physical Review Letters},\\n number = {24}\\n}\",\"author_short\":[\"Gatto Lamas,  A.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/16d6853b-76ac-6373-1c19-08ffea9cac0b/Chitambar_2023_Multipartite_Nonlocality_in_Clifford_Networks.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"gattolamas-chitambar-multipartitenonlocalityincliffordnetworks-2023\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Reexamination of quantum state transformations with zero communication\",\"type\":\"article\",\"year\":\"2024\",\"volume\":\"109\",\"month\":\"6\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"7287fa47-6973-3445-9c4a-b9c608485e5e\",\"created\":\"2025-04-11T23:19:47.362Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-11T23:20:56.703Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"It is known that general convertibility of bipartite entangled states is not possible to arbitrary error without some classical communication. While some tradeoffs between communication cost and conversion error have been proven, these bounds can be very loose. In particular, there are many cases in which tolerable error might be achievable using zero-communication protocols. In this work we address these cases by deriving the optimal fidelity of pure quantum state conversions under local unitaries as well as local operations and shared randomness. We also use these results to explore catalytic conversions between pure states using zero communication.\",\"bibtype\":\"article\",\"author\":\"George, Ian and Chitambar, Eric\",\"doi\":\"10.1103/PhysRevA.109.062418\",\"journal\":\"Physical Review A\",\"number\":\"6\",\"bibtex\":\"@article{\\n title = {Reexamination of quantum state transformations with zero communication},\\n type = {article},\\n year = {2024},\\n volume = {109},\\n month = {6},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {7287fa47-6973-3445-9c4a-b9c608485e5e},\\n created = {2025-04-11T23:19:47.362Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-11T23:20:56.703Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {It is known that general convertibility of bipartite entangled states is not possible to arbitrary error without some classical communication. While some tradeoffs between communication cost and conversion error have been proven, these bounds can be very loose. In particular, there are many cases in which tolerable error might be achievable using zero-communication protocols. In this work we address these cases by deriving the optimal fidelity of pure quantum state conversions under local unitaries as well as local operations and shared randomness. We also use these results to explore catalytic conversions between pure states using zero communication.},\\n bibtype = {article},\\n author = {George, Ian and Chitambar, Eric},\\n doi = {10.1103/PhysRevA.109.062418},\\n journal = {Physical Review A},\\n number = {6}\\n}\",\"author_short\":[\"George,  I.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/63ab2c67-2f71-1dcf-07e0-672d4dacad37/Chitambar_2024_Reexamination_of_quantum_state_transformation.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"george-chitambar-reexaminationofquantumstatetransformationswithzerocommunication-2024\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Exact Steering Bound for Two-Qubit Werner States\",\"type\":\"article\",\"year\":\"2024\",\"volume\":\"132\",\"month\":\"6\",\"publisher\":\"American Physical Society\",\"day\":\"21\",\"id\":\"0385ce87-2776-3d90-9d47-b102269cdc3c\",\"created\":\"2025-04-11T23:19:47.397Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-11T23:20:53.166Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Whether positive operator-valued measures (POVMs) provide advantages in demonstrating Bell nonlocality has remained unknown, even in the simple scenario of Einstein-Podolsky-Rosen steering with noisy singlet state, known as Werner states. Here we resolve this long-standing open problem by constructing a local hidden state model for Werner states with any visibility r≤1/2 under general POVMs, thereby closing the so-called Werner gap. This construction is based on an exact measurement compatibility model for the set of all noisy POVMs and also provides a local hidden variable model for a larger range of Werner states than previously known.\",\"bibtype\":\"article\",\"author\":\"Zhang, Yujie and Chitambar, Eric\",\"doi\":\"10.1103/PhysRevLett.132.250201\",\"journal\":\"Physical Review Letters\",\"number\":\"25\",\"bibtex\":\"@article{\\n title = {Exact Steering Bound for Two-Qubit Werner States},\\n type = {article},\\n year = {2024},\\n volume = {132},\\n month = {6},\\n publisher = {American Physical Society},\\n day = {21},\\n id = {0385ce87-2776-3d90-9d47-b102269cdc3c},\\n created = {2025-04-11T23:19:47.397Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-11T23:20:53.166Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Whether positive operator-valued measures (POVMs) provide advantages in demonstrating Bell nonlocality has remained unknown, even in the simple scenario of Einstein-Podolsky-Rosen steering with noisy singlet state, known as Werner states. Here we resolve this long-standing open problem by constructing a local hidden state model for Werner states with any visibility r≤1/2 under general POVMs, thereby closing the so-called Werner gap. This construction is based on an exact measurement compatibility model for the set of all noisy POVMs and also provides a local hidden variable model for a larger range of Werner states than previously known.},\\n bibtype = {article},\\n author = {Zhang, Yujie and Chitambar, Eric},\\n doi = {10.1103/PhysRevLett.132.250201},\\n journal = {Physical Review Letters},\\n number = {25}\\n}\",\"author_short\":[\"Zhang,  Y.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/34968950-2132-0545-73a7-c55ab0bcae63/Chitambar_2024_Exact_Steering_Bound_for_Two_Qubit_Werner_Sta.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"zhang-chitambar-exactsteeringboundfortwoqubitwernerstates-2024\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Reliable quantum memories with unreliable components\",\"type\":\"article\",\"year\":\"2024\",\"pages\":\"032423\",\"volume\":\"110\",\"websites\":\"https://link.aps.org/doi/10.1103/PhysRevA.110.032423\",\"month\":\"9\",\"day\":\"18\",\"id\":\"68d07fba-57ea-32d6-bb8d-94742cf3c7ed\",\"created\":\"2025-04-11T23:19:47.953Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-11T23:20:50.118Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"bibtype\":\"article\",\"author\":\"Nayak, Anuj K. and Chitambar, Eric and Varshney, Lav R.\",\"doi\":\"10.1103/PhysRevA.110.032423\",\"journal\":\"Physical Review A\",\"number\":\"3\",\"bibtex\":\"@article{\\n title = {Reliable quantum memories with unreliable components},\\n type = {article},\\n year = {2024},\\n pages = {032423},\\n volume = {110},\\n websites = {https://link.aps.org/doi/10.1103/PhysRevA.110.032423},\\n month = {9},\\n day = {18},\\n id = {68d07fba-57ea-32d6-bb8d-94742cf3c7ed},\\n created = {2025-04-11T23:19:47.953Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-11T23:20:50.118Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n bibtype = {article},\\n author = {Nayak, Anuj K. and Chitambar, Eric and Varshney, Lav R.},\\n doi = {10.1103/PhysRevA.110.032423},\\n journal = {Physical Review A},\\n number = {3}\\n}\",\"author_short\":[\"Nayak,  A., K.\",\"Chitambar,  E.\",\"Varshney,  L., R.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/26c9a6a9-600d-1f67-5f6f-238813ccaf8f/Varshney_2024_Reliable_quantum_memories_with_unreliable_comp.pdf.pdf\",\"Website\":\"https://link.aps.org/doi/10.1103/PhysRevA.110.032423\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"nayak-chitambar-varshney-reliablequantummemorieswithunreliablecomponents-2024\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Building Multiple Access Channels with a Single Particle\",\"type\":\"article\",\"year\":\"2022\",\"volume\":\"6\",\"publisher\":\"Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften\",\"id\":\"4f4a3703-5a5f-3776-8e5a-3fe9784a02ea\",\"created\":\"2025-04-11T23:19:49.064Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T18:11:37.156Z\",\"read\":\"true\",\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"A multiple access channel describes a situation in which multiple senders are trying to forward messages to a single receiver using some physical medium. In this paper we consider scenarios in which this medium consists of just a single classical or quantum particle. In the quantum case, the particle can be prepared in a superposition state thereby allowing for a richer family of encoding strategies. To make the comparison between quantum and classical channels precise, we introduce an operational framework in which all possible encoding strategies consume no more than a single particle. We apply this framework to an Nport interferometer experiment in which each party controls a path the particle can traverse. When used for the purpose of communication, this setup embodies a multiple access channel (MAC) built with a single particle. We provide a full characterization of the Nparty classical MACs that can be built from a single particle, and we show that every quantum particle can generate a MAC outside the classical set. To further distinguish the capabilities of a single classical and quantum particle, we relax the locality constraint and allow for joint encodings by subsets of 1 < K ≤ N parties. This generates a richer family of classical MACs whose polytope dimension we compute. We identify a \\\"generalized fingerprinting inequality\\\" as a valid facet for this polytope, and we verify that a quantum particle distributed among N separated parties can violate this inequality even when K = N-1. Connections are drawn between the single-particle framework and multi-level coherence theory. We show that every pure state with K-level coherence can be detected in a semi-device independent manner, with the only assumption being conservation of particle number.\",\"bibtype\":\"article\",\"author\":\"Zhang, Yujie and Chen, Xinan and Chitambar, Eric\",\"doi\":\"10.22331/Q-2022-02-16-653\",\"journal\":\"Quantum\",\"bibtex\":\"@article{\\n title = {Building Multiple Access Channels with a Single Particle},\\n type = {article},\\n year = {2022},\\n volume = {6},\\n publisher = {Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften},\\n id = {4f4a3703-5a5f-3776-8e5a-3fe9784a02ea},\\n created = {2025-04-11T23:19:49.064Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T18:11:37.156Z},\\n read = {true},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {A multiple access channel describes a situation in which multiple senders are trying to forward messages to a single receiver using some physical medium. In this paper we consider scenarios in which this medium consists of just a single classical or quantum particle. In the quantum case, the particle can be prepared in a superposition state thereby allowing for a richer family of encoding strategies. To make the comparison between quantum and classical channels precise, we introduce an operational framework in which all possible encoding strategies consume no more than a single particle. We apply this framework to an Nport interferometer experiment in which each party controls a path the particle can traverse. When used for the purpose of communication, this setup embodies a multiple access channel (MAC) built with a single particle. We provide a full characterization of the Nparty classical MACs that can be built from a single particle, and we show that every quantum particle can generate a MAC outside the classical set. To further distinguish the capabilities of a single classical and quantum particle, we relax the locality constraint and allow for joint encodings by subsets of 1 < K ≤ N parties. This generates a richer family of classical MACs whose polytope dimension we compute. We identify a \\\"generalized fingerprinting inequality\\\" as a valid facet for this polytope, and we verify that a quantum particle distributed among N separated parties can violate this inequality even when K = N-1. Connections are drawn between the single-particle framework and multi-level coherence theory. We show that every pure state with K-level coherence can be detected in a semi-device independent manner, with the only assumption being conservation of particle number.},\\n bibtype = {article},\\n author = {Zhang, Yujie and Chen, Xinan and Chitambar, Eric},\\n doi = {10.22331/Q-2022-02-16-653},\\n journal = {Quantum}\\n}\",\"author_short\":[\"Zhang,  Y.\",\"Chen,  X.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/08210d90-275e-4e81-36fd-dfe2d9ecb1e7/Chitambar_2022_Building_Multiple_Access_Channels_with_a_Sing.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"zhang-chen-chitambar-buildingmultipleaccesschannelswithasingleparticle-2022\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Variational Quantum Optimization of Nonlocality in Noisy Quantum Networks\",\"type\":\"article\",\"year\":\"2023\",\"keywords\":\"Design and simulation tools,noisy intermediate-scale quantum (NISQ) algorithms and devices,quantum networking\",\"volume\":\"4\",\"publisher\":\"Institute of Electrical and Electronics Engineers Inc.\",\"id\":\"f48dc44d-f1ae-3347-a029-cdc9bdd476f5\",\"created\":\"2025-04-11T23:19:49.242Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-11T23:20:42.332Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"The noise and complexity inherent to quantum communication networks leads to technical challenges in designing quantum network protocols using classical methods. We address this issue with a hybrid variational quantum optimization (VQO) framework that simulates quantum networks on quantum hardware and optimizes the simulation using differential programming. We maximize nonlocality in noisy quantum networks to showcase our VQO framework. Using a classical simulator, we investigate the noise robustness of quantum nonlocality. Our VQO methods reproduce known results and uncover novel phenomena. We find that maximally entangled states maximize nonlocality in the presence of unital qubit channels, while nonmaximally entangled states can maximize nonlocality in the presence of nonunital qubit channels. Thus, we show VQO to be a practical design tool for quantum networks even when run on a classical simulator. Finally, using IBM quantum computers, we demonstrate that our VQO framework can maximize nonlocality on noisy quantum hardware. In the long term, our VQO techniques show promise of scaling beyond classical approaches and can be deployed on quantum network hardware to optimize network protocols against their inherent noise.\",\"bibtype\":\"article\",\"author\":\"Doolittle, Brian and Bromley, R. Thomas and Killoran, Nathan and Chitambar, Eric\",\"doi\":\"10.1109/TQE.2023.3243849\",\"journal\":\"IEEE Transactions on Quantum Engineering\",\"bibtex\":\"@article{\\n title = {Variational Quantum Optimization of Nonlocality in Noisy Quantum Networks},\\n type = {article},\\n year = {2023},\\n keywords = {Design and simulation tools,noisy intermediate-scale quantum (NISQ) algorithms and devices,quantum networking},\\n volume = {4},\\n publisher = {Institute of Electrical and Electronics Engineers Inc.},\\n id = {f48dc44d-f1ae-3347-a029-cdc9bdd476f5},\\n created = {2025-04-11T23:19:49.242Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-11T23:20:42.332Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {The noise and complexity inherent to quantum communication networks leads to technical challenges in designing quantum network protocols using classical methods. We address this issue with a hybrid variational quantum optimization (VQO) framework that simulates quantum networks on quantum hardware and optimizes the simulation using differential programming. We maximize nonlocality in noisy quantum networks to showcase our VQO framework. Using a classical simulator, we investigate the noise robustness of quantum nonlocality. Our VQO methods reproduce known results and uncover novel phenomena. We find that maximally entangled states maximize nonlocality in the presence of unital qubit channels, while nonmaximally entangled states can maximize nonlocality in the presence of nonunital qubit channels. Thus, we show VQO to be a practical design tool for quantum networks even when run on a classical simulator. Finally, using IBM quantum computers, we demonstrate that our VQO framework can maximize nonlocality on noisy quantum hardware. In the long term, our VQO techniques show promise of scaling beyond classical approaches and can be deployed on quantum network hardware to optimize network protocols against their inherent noise.},\\n bibtype = {article},\\n author = {Doolittle, Brian and Bromley, R. Thomas and Killoran, Nathan and Chitambar, Eric},\\n doi = {10.1109/TQE.2023.3243849},\\n journal = {IEEE Transactions on Quantum Engineering}\\n}\",\"author_short\":[\"Doolittle,  B.\",\"Bromley,  R., T.\",\"Killoran,  N.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7d02becd-af4d-2057-0e8c-9c3da00cb43f/Chitambar_2023_Variational_Quantum_Optimization_of_Nonlocali.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"doolittle-bromley-killoran-chitambar-variationalquantumoptimizationofnonlocalityinnoisyquantumnetworks-2023\",\"role\":\"author\",\"keyword\":[\"Design and simulation tools\",\"noisy intermediate-scale quantum (NISQ) algorithms and devices\",\"quantum networking\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Information carried by a single particle in quantum multiple-access channels\",\"type\":\"article\",\"year\":\"2024\",\"volume\":\"109\",\"month\":\"6\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"50e5332f-f2ce-3875-9551-af5879f171fc\",\"created\":\"2025-04-11T23:19:49.710Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-11T23:20:38.574Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Nonclassical features of quantum systems have the potential to strengthen the way we currently exchange information. In this paper, we explore this enhancement on the most basic level of single particles. To be more precise, we compare how well multiparty information can be transmitted to a single receiver using just one classical or quantum particle. Our approach is based on a multiple-access communication model in which messages can be encoded into a single particle that is coherently distributed across multiple spatial modes. Theoretically, we derive lower bounds on the accessible information in the quantum setting that strictly separate it from the classical scenario. This separation is found whenever there is more than one sender, and also when there is just a single sender who has a shared phase reference with the receiver. When there is only one sender, the separation is impossible without a shared phase reference due to the famous Holevo's bound. Experimentally, we present a proof-of-principle demonstration of such quantum advantage in single-particle communication by implementing a multiport interferometer with messages being encoded along the different trajectories. Specifically, we consider a two-sender communication protocol built by a three-port optical interferometer. In this scenario, the rate sum achievable with a classical particle is upper bounded by one bit, while we experimentally observe a rate sum of 1.0152±0.0034 bits in the quantum setup.\",\"bibtype\":\"article\",\"author\":\"Chen, Xinan and Zhang, Yujie and Winter, Andreas and Lorenz, Virginia O. and Chitambar, Eric\",\"doi\":\"10.1103/PhysRevA.109.062420\",\"journal\":\"Physical Review A\",\"number\":\"6\",\"bibtex\":\"@article{\\n title = {Information carried by a single particle in quantum multiple-access channels},\\n type = {article},\\n year = {2024},\\n volume = {109},\\n month = {6},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {50e5332f-f2ce-3875-9551-af5879f171fc},\\n created = {2025-04-11T23:19:49.710Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-11T23:20:38.574Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Nonclassical features of quantum systems have the potential to strengthen the way we currently exchange information. In this paper, we explore this enhancement on the most basic level of single particles. To be more precise, we compare how well multiparty information can be transmitted to a single receiver using just one classical or quantum particle. Our approach is based on a multiple-access communication model in which messages can be encoded into a single particle that is coherently distributed across multiple spatial modes. Theoretically, we derive lower bounds on the accessible information in the quantum setting that strictly separate it from the classical scenario. This separation is found whenever there is more than one sender, and also when there is just a single sender who has a shared phase reference with the receiver. When there is only one sender, the separation is impossible without a shared phase reference due to the famous Holevo's bound. Experimentally, we present a proof-of-principle demonstration of such quantum advantage in single-particle communication by implementing a multiport interferometer with messages being encoded along the different trajectories. Specifically, we consider a two-sender communication protocol built by a three-port optical interferometer. In this scenario, the rate sum achievable with a classical particle is upper bounded by one bit, while we experimentally observe a rate sum of 1.0152±0.0034 bits in the quantum setup.},\\n bibtype = {article},\\n author = {Chen, Xinan and Zhang, Yujie and Winter, Andreas and Lorenz, Virginia O. and Chitambar, Eric},\\n doi = {10.1103/PhysRevA.109.062420},\\n journal = {Physical Review A},\\n number = {6}\\n}\",\"author_short\":[\"Chen,  X.\",\"Zhang,  Y.\",\"Winter,  A.\",\"Lorenz,  V., O.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/723b9bc9-2565-2039-661b-5898662cb697/Chitambar_2024_Information_carried_by_a_single_particle_in_q.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chen-zhang-winter-lorenz-chitambar-informationcarriedbyasingleparticleinquantummultipleaccesschannels-2024\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Inferring Quantum Network Topology Using Local Measurements\",\"type\":\"article\",\"year\":\"2023\",\"volume\":\"4\",\"month\":\"10\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"c5331bbe-92af-3034-851f-00d0f36141f2\",\"created\":\"2025-04-11T23:19:51.710Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-11T23:20:33.438Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Statistical correlations that can be generated across the nodes in a quantum network depend crucially on its topology. However, this topological information might not be known a priori, or it may need to be verified. In this paper, we propose an efficient protocol for distinguishing and inferring the topology of a quantum network. We leverage entropic quantities - namely, the von Neumann entropy and the measured mutual information - as well as measurement covariance to uniquely characterize the topology. We show that the entropic quantities are sufficient to distinguish two networks that prepare GHZ states. Moreover, if qubit measurements are available, both entropic quantities and covariance can be used to infer the network topology without state-preparation assumptions. We show that the protocol can be entirely robust to noise and can be implemented via quantum variational optimization. Numerical experiments on both classical simulators and quantum hardware show that covariance is generally more reliable for accurately and efficiently inferring the topology, whereas entropy-based methods are often better at identifying the absence of entanglement in the low-shot regime.\",\"bibtype\":\"article\",\"author\":\"Chen, Daniel T. and Doolittle, Brian and Larson, Jeffrey and Saleem, Zain H. and Chitambar, Eric\",\"doi\":\"10.1103/PRXQuantum.4.040347\",\"journal\":\"PRX Quantum\",\"number\":\"4\",\"bibtex\":\"@article{\\n title = {Inferring Quantum Network Topology Using Local Measurements},\\n type = {article},\\n year = {2023},\\n volume = {4},\\n month = {10},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {c5331bbe-92af-3034-851f-00d0f36141f2},\\n created = {2025-04-11T23:19:51.710Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-11T23:20:33.438Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Statistical correlations that can be generated across the nodes in a quantum network depend crucially on its topology. However, this topological information might not be known a priori, or it may need to be verified. In this paper, we propose an efficient protocol for distinguishing and inferring the topology of a quantum network. We leverage entropic quantities - namely, the von Neumann entropy and the measured mutual information - as well as measurement covariance to uniquely characterize the topology. We show that the entropic quantities are sufficient to distinguish two networks that prepare GHZ states. Moreover, if qubit measurements are available, both entropic quantities and covariance can be used to infer the network topology without state-preparation assumptions. We show that the protocol can be entirely robust to noise and can be implemented via quantum variational optimization. Numerical experiments on both classical simulators and quantum hardware show that covariance is generally more reliable for accurately and efficiently inferring the topology, whereas entropy-based methods are often better at identifying the absence of entanglement in the low-shot regime.},\\n bibtype = {article},\\n author = {Chen, Daniel T. and Doolittle, Brian and Larson, Jeffrey and Saleem, Zain H. and Chitambar, Eric},\\n doi = {10.1103/PRXQuantum.4.040347},\\n journal = {PRX Quantum},\\n number = {4}\\n}\",\"author_short\":[\"Chen,  D., T.\",\"Doolittle,  B.\",\"Larson,  J.\",\"Saleem,  Z., H.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/638d802e-43c2-3359-1538-d14df26cbb47/Chitambar_2023_Inferring_Quantum_Network_Topology_Using_Loca.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chen-doolittle-larson-saleem-chitambar-inferringquantumnetworktopologyusinglocalmeasurements-2023\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"html\":\"\"},{\"title\":\"Entanglement Verification of Hyperentangled Photon Pairs\",\"type\":\"article\",\"year\":\"2022\",\"volume\":\"18\",\"month\":\"11\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"8a9f051f-b0dc-3315-8b21-18ed127a5b67\",\"created\":\"2025-04-12T17:53:42.945Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T18:04:22.009Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"We experimentally investigate the properties of hyperentangled states displaying simultaneous entanglement in multiple degrees of freedom and find that Bell tests beyond the standard Clauser-Horne-Shimony-Holt inequality can reveal a higher-dimensional nature in a device-independent way. Specifically, we show that hyperentangled states possess more than just simultaneous entanglement in separate degrees of freedom but also entanglement in a higher-dimensional Hilbert space. We also verify the steerability of hyperentangled quantum states by steering different photonic degrees of freedom.\",\"bibtype\":\"article\",\"author\":\"Zeitler, Christopher K. and Chapman, Joseph C. and Chitambar, Eric and Kwiat, Paul G.\",\"doi\":\"10.1103/PhysRevApplied.18.054025\",\"journal\":\"Physical Review Applied\",\"number\":\"5\",\"bibtex\":\"@article{\\n title = {Entanglement Verification of Hyperentangled Photon Pairs},\\n type = {article},\\n year = {2022},\\n volume = {18},\\n month = {11},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {8a9f051f-b0dc-3315-8b21-18ed127a5b67},\\n created = {2025-04-12T17:53:42.945Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T18:04:22.009Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {We experimentally investigate the properties of hyperentangled states displaying simultaneous entanglement in multiple degrees of freedom and find that Bell tests beyond the standard Clauser-Horne-Shimony-Holt inequality can reveal a higher-dimensional nature in a device-independent way. Specifically, we show that hyperentangled states possess more than just simultaneous entanglement in separate degrees of freedom but also entanglement in a higher-dimensional Hilbert space. We also verify the steerability of hyperentangled quantum states by steering different photonic degrees of freedom.},\\n bibtype = {article},\\n author = {Zeitler, Christopher K. and Chapman, Joseph C. and Chitambar, Eric and Kwiat, Paul G.},\\n doi = {10.1103/PhysRevApplied.18.054025},\\n journal = {Physical Review Applied},\\n number = {5}\\n}\",\"author_short\":[\"Zeitler,  C., K.\",\"Chapman,  J., C.\",\"Chitambar,  E.\",\"Kwiat,  P., G.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/435b4d80-b466-54b7-3467-756ef36af973/Zeitler_2022_Entanglement_Verification_of_Hyperentangled_Pho.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"zeitler-chapman-chitambar-kwiat-entanglementverificationofhyperentangledphotonpairs-2022\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Maximal qubit violations of n -locality in star and chain networks\",\"type\":\"article\",\"year\":\"2023\",\"volume\":\"108\",\"month\":\"10\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"1154cbff-cca3-3080-bdaf-8c4a7a9538c2\",\"created\":\"2025-04-12T17:56:25.189Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T18:03:57.166Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"The nonlocal correlations of noisy quantum systems are important for both understanding nature and developing quantum technology. We consider the correlations of star and chain quantum networks in which noisy entanglement sources are measured by nonsignaling parties. We derive the necessary and sufficient conditions for when a broad family of star and chain n-locality inequalities achieve their maximal quantum violation assuming that each party's dichotomic observables are separable across qudit systems. When pairs of local dichotomic observables are considered on qubit systems, we derive maximal n-local violations that are larger and more robust to noise than the maximal n-locality violations reported previously. To obtain these larger values, we consider observables that we have not found in previous studies. Thus, we gain insights into self-testing entanglement sources and measurements in star and chain networks.\",\"bibtype\":\"article\",\"author\":\"Doolittle, Brian and Chitambar, Eric\",\"doi\":\"10.1103/PhysRevA.108.042409\",\"journal\":\"Physical Review A\",\"number\":\"4\",\"bibtex\":\"@article{\\n title = {Maximal qubit violations of n -locality in star and chain networks},\\n type = {article},\\n year = {2023},\\n volume = {108},\\n month = {10},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {1154cbff-cca3-3080-bdaf-8c4a7a9538c2},\\n created = {2025-04-12T17:56:25.189Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T18:03:57.166Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {The nonlocal correlations of noisy quantum systems are important for both understanding nature and developing quantum technology. We consider the correlations of star and chain quantum networks in which noisy entanglement sources are measured by nonsignaling parties. We derive the necessary and sufficient conditions for when a broad family of star and chain n-locality inequalities achieve their maximal quantum violation assuming that each party's dichotomic observables are separable across qudit systems. When pairs of local dichotomic observables are considered on qubit systems, we derive maximal n-local violations that are larger and more robust to noise than the maximal n-locality violations reported previously. To obtain these larger values, we consider observables that we have not found in previous studies. Thus, we gain insights into self-testing entanglement sources and measurements in star and chain networks.},\\n bibtype = {article},\\n author = {Doolittle, Brian and Chitambar, Eric},\\n doi = {10.1103/PhysRevA.108.042409},\\n journal = {Physical Review A},\\n number = {4}\\n}\",\"author_short\":[\"Doolittle,  B.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4eb2aa2c-e91d-2009-2c83-3094be2b7803/Doolittle_2023_Maximal_qubit_violations_of_n_locality_in_sta.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"doolittle-chitambar-maximalqubitviolationsofnlocalityinstarandchainnetworks-2023\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Cone-restricted information theory\",\"type\":\"article\",\"year\":\"2024\",\"keywords\":\"conic programming,convex geometry,quantum entropies,quantum information theory\",\"volume\":\"57\",\"month\":\"6\",\"publisher\":\"Institute of Physics\",\"day\":\"28\",\"id\":\"c39258e0-d504-324c-8855-3f591d4dda3f\",\"created\":\"2025-04-12T17:56:44.686Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T18:03:24.095Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"The max-relative entropy and the conditional min-entropy of a quantum state plays a central role in one-shot and zero-error quantum information theory. One attractive feature of this quantity is that it can be expressed as an optimization over the cone of positive semidefinite operators. Recently, it was shown that when replacing this cone with the cone of separable operators, a new type of conditional min-entropy emerges that admits an operational interpretation in terms of communicating classical information over a quantum channel. In this work, we explore more deeply the idea of building information-theoretic quantities from different base cones and determine which results in quantum information theory rely upon the positive semidefinite cone and which can be generalized. In terms of asymptotic information processing, we find that the standard equipartition properties break down if a given cone fails to approximate the positive semidefinite cone sufficiently well. We also show that the near-equivalence of the smooth max and Hartley entropies breaks down in this setting. We present parallel results for the extended conditional min-entropy, which requires extending the notion of k-superpositive channels to superchannels. On the other hand, we show that for classical-quantum states the separable cone is sufficient to re-cover the asymptotic theory, thereby drawing a strong distinction between the fully and partial quantum settings. We also present operational uses of this framework. We show that the cone restricted min-entropy of a Choi operator captures a measure of entanglement-assisted noiseless classical communication using restricted measurements. We also introduce a novel min-entropy-like quantity that captures the conditions for when one quantum channel can be transformed into another using bistochastic pre-processing. Lastly, we relate this framework to general conic norms and their non-additivity. Throughout this work, we concretely study generalized entropies in resource theories that capture locality and resource theories of coherence/Abelian symmetries.\",\"bibtype\":\"article\",\"author\":\"George, Ian and Chitambar, Eric\",\"doi\":\"10.1088/1751-8121/ad52d5\",\"journal\":\"Journal of Physics A: Mathematical and Theoretical\",\"number\":\"26\",\"bibtex\":\"@article{\\n title = {Cone-restricted information theory},\\n type = {article},\\n year = {2024},\\n keywords = {conic programming,convex geometry,quantum entropies,quantum information theory},\\n volume = {57},\\n month = {6},\\n publisher = {Institute of Physics},\\n day = {28},\\n id = {c39258e0-d504-324c-8855-3f591d4dda3f},\\n created = {2025-04-12T17:56:44.686Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T18:03:24.095Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {The max-relative entropy and the conditional min-entropy of a quantum state plays a central role in one-shot and zero-error quantum information theory. One attractive feature of this quantity is that it can be expressed as an optimization over the cone of positive semidefinite operators. Recently, it was shown that when replacing this cone with the cone of separable operators, a new type of conditional min-entropy emerges that admits an operational interpretation in terms of communicating classical information over a quantum channel. In this work, we explore more deeply the idea of building information-theoretic quantities from different base cones and determine which results in quantum information theory rely upon the positive semidefinite cone and which can be generalized. In terms of asymptotic information processing, we find that the standard equipartition properties break down if a given cone fails to approximate the positive semidefinite cone sufficiently well. We also show that the near-equivalence of the smooth max and Hartley entropies breaks down in this setting. We present parallel results for the extended conditional min-entropy, which requires extending the notion of k-superpositive channels to superchannels. On the other hand, we show that for classical-quantum states the separable cone is sufficient to re-cover the asymptotic theory, thereby drawing a strong distinction between the fully and partial quantum settings. We also present operational uses of this framework. We show that the cone restricted min-entropy of a Choi operator captures a measure of entanglement-assisted noiseless classical communication using restricted measurements. We also introduce a novel min-entropy-like quantity that captures the conditions for when one quantum channel can be transformed into another using bistochastic pre-processing. Lastly, we relate this framework to general conic norms and their non-additivity. Throughout this work, we concretely study generalized entropies in resource theories that capture locality and resource theories of coherence/Abelian symmetries.},\\n bibtype = {article},\\n author = {George, Ian and Chitambar, Eric},\\n doi = {10.1088/1751-8121/ad52d5},\\n journal = {Journal of Physics A: Mathematical and Theoretical},\\n number = {26}\\n}\",\"author_short\":[\"George,  I.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/15f1a428-2836-242f-1ef6-c3d2739b8037/George_2024_Cone_restricted_information_theory.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"george-chitambar-conerestrictedinformationtheory-2024\",\"role\":\"author\",\"keyword\":[\"conic programming\",\"convex geometry\",\"quantum entropies\",\"quantum information theory\"],\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Process-optimized phase-covariant quantum cloning\",\"type\":\"article\",\"year\":\"2022\",\"volume\":\"106\",\"month\":\"8\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"71a72245-5ac8-3607-a817-ba8988e88461\",\"created\":\"2025-04-12T18:01:03.461Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T18:04:26.628Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"After the appearance of the no-cloning theorem, approximate quantum cloning machines (QCMs) has become a well-studied subject in quantum information theory. Among several measures to quantify the performance of a QCM, single-qudit fidelity and global fidelity have been most widely used. In this paper we compute the optimal global fidelity for phase-covariant cloning machines via semidefinite programming optimization, thereby completing a remaining gap in the previous results on QCMs. We also consider optimal simulations of the cloning and transpose cloning map, both by a direct optimization and by a composition of component-wise optimal QCMs. For the cloning map the composition method is suboptimal whereas for the transpose cloning map the method is asymptotically optimal.\",\"bibtype\":\"article\",\"author\":\"Kim, Chloe and Chitambar, Eric\",\"doi\":\"10.1103/PhysRevA.106.022405\",\"journal\":\"Physical Review A\",\"number\":\"2\",\"bibtex\":\"@article{\\n title = {Process-optimized phase-covariant quantum cloning},\\n type = {article},\\n year = {2022},\\n volume = {106},\\n month = {8},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {71a72245-5ac8-3607-a817-ba8988e88461},\\n created = {2025-04-12T18:01:03.461Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T18:04:26.628Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {After the appearance of the no-cloning theorem, approximate quantum cloning machines (QCMs) has become a well-studied subject in quantum information theory. Among several measures to quantify the performance of a QCM, single-qudit fidelity and global fidelity have been most widely used. In this paper we compute the optimal global fidelity for phase-covariant cloning machines via semidefinite programming optimization, thereby completing a remaining gap in the previous results on QCMs. We also consider optimal simulations of the cloning and transpose cloning map, both by a direct optimization and by a composition of component-wise optimal QCMs. For the cloning map the composition method is suboptimal whereas for the transpose cloning map the method is asymptotically optimal.},\\n bibtype = {article},\\n author = {Kim, Chloe and Chitambar, Eric},\\n doi = {10.1103/PhysRevA.106.022405},\\n journal = {Physical Review A},\\n number = {2}\\n}\",\"author_short\":[\"Kim,  C.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/5fafc9ea-ed7e-50d9-1676-77134cec4193/Kim_2022_Process_optimized_phase_covariant_quantum_cloning.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"kim-chitambar-processoptimizedphasecovariantquantumcloning-2022\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Quantum telescopy clock games\",\"type\":\"article\",\"year\":\"2022\",\"volume\":\"106\",\"month\":\"9\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"ebbc76a5-436e-3500-a6a6-9e0e5183a6e0\",\"created\":\"2025-04-12T18:01:03.649Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T18:04:31.535Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"We consider the clock game-a task formulated in the framework of quantum information theory - that can be used to improve the existing schemes of quantum-enhanced telescopy. The problem of learning when a stellar photon reaches a telescope is translated into an abstract game, which we call the clock game. A winning strategy is provided that involves performing a quantum non-demolition measurement that verifies which stellar spatio-temporal modes are occupied by a photon without disturbing the phase information. We prove tight lower bounds on the entanglement cost needed to win the clock game, with the amount of necessary entangled bits equaling the number of time bins being distinguished. This lower bound on the entanglement cost applies to any telescopy protocol that aims to nondestructively extract the time bin information of an incident photon through local measurements, and our result implies that the protocol of Khabiboulline et al. [Phys. Rev. Lett. 123, 070504 (2019)0031-900710.1103/PhysRevLett.123.070504] is optimal in terms of entanglement consumption. The full task of the phase extraction is also considered, and we show that the quantum Fisher information of the stellar phase can be achieved by local measurements and shared entanglement without the necessity of nonlinear optical operations. The optimal phase measurement is achieved asymptotically with increasing number of ancilla qubits, whereas a single qubit pair is required if nonlinear operations are allowed.\",\"bibtype\":\"article\",\"author\":\"Czupryniak, Robert and Chitambar, Eric and Steinmetz, John and Jordan, Andrew N.\",\"doi\":\"10.1103/PhysRevA.106.032424\",\"journal\":\"Physical Review A\",\"number\":\"3\",\"bibtex\":\"@article{\\n title = {Quantum telescopy clock games},\\n type = {article},\\n year = {2022},\\n volume = {106},\\n month = {9},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {ebbc76a5-436e-3500-a6a6-9e0e5183a6e0},\\n created = {2025-04-12T18:01:03.649Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T18:04:31.535Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {We consider the clock game-a task formulated in the framework of quantum information theory - that can be used to improve the existing schemes of quantum-enhanced telescopy. The problem of learning when a stellar photon reaches a telescope is translated into an abstract game, which we call the clock game. A winning strategy is provided that involves performing a quantum non-demolition measurement that verifies which stellar spatio-temporal modes are occupied by a photon without disturbing the phase information. We prove tight lower bounds on the entanglement cost needed to win the clock game, with the amount of necessary entangled bits equaling the number of time bins being distinguished. This lower bound on the entanglement cost applies to any telescopy protocol that aims to nondestructively extract the time bin information of an incident photon through local measurements, and our result implies that the protocol of Khabiboulline et al. [Phys. Rev. Lett. 123, 070504 (2019)0031-900710.1103/PhysRevLett.123.070504] is optimal in terms of entanglement consumption. The full task of the phase extraction is also considered, and we show that the quantum Fisher information of the stellar phase can be achieved by local measurements and shared entanglement without the necessity of nonlinear optical operations. The optimal phase measurement is achieved asymptotically with increasing number of ancilla qubits, whereas a single qubit pair is required if nonlinear operations are allowed.},\\n bibtype = {article},\\n author = {Czupryniak, Robert and Chitambar, Eric and Steinmetz, John and Jordan, Andrew N.},\\n doi = {10.1103/PhysRevA.106.032424},\\n journal = {Physical Review A},\\n number = {3}\\n}\",\"author_short\":[\"Czupryniak,  R.\",\"Chitambar,  E.\",\"Steinmetz,  J.\",\"Jordan,  A., N.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/1e9c8e72-8a22-a2d3-023d-d540affc42bf/Czupryniak_2022_Quantum_telescopy_clock_games.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"czupryniak-chitambar-steinmetz-jordan-quantumtelescopyclockgames-2022\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Certifying the classical simulation cost of a quantum channel\",\"type\":\"article\",\"year\":\"2021\",\"volume\":\"3\",\"month\":\"12\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"12f24a7c-b1a5-339f-8f03-334ad0e1dbc5\",\"created\":\"2025-04-12T18:01:04.723Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T18:04:35.993Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"A fundamental objective in quantum information science is to determine the cost in classical resources of simulating a particular quantum system. The classical simulation cost is quantified by the signaling dimension which specifies the minimum amount of classical communication needed to perfectly simulate a channel's input-output correlations when unlimited shared randomness is held between encoder and decoder. This paper provides a collection of device-independent tests that place lower and upper bounds on the signaling dimension of a channel. Among them, a single family of tests is shown to determine when a noisy classical channel can be simulated using an amount of communication strictly less than either its input or its output alphabet size. In addition, a family of eight signaling dimension witnesses is presented that completely characterize when any four-outcome measurement channel, such as a Bell measurement, can be simulated using one communication bit and shared randomness. Finally, we bound the signaling dimension for all partial replacer channels in d dimensions. The bounds are found to be tight for the special case of the erasure channel.\",\"bibtype\":\"article\",\"author\":\"Doolittle, Brian and Chitambar, Eric\",\"doi\":\"10.1103/PhysRevResearch.3.043073\",\"journal\":\"Physical Review Research\",\"number\":\"4\",\"bibtex\":\"@article{\\n title = {Certifying the classical simulation cost of a quantum channel},\\n type = {article},\\n year = {2021},\\n volume = {3},\\n month = {12},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {12f24a7c-b1a5-339f-8f03-334ad0e1dbc5},\\n created = {2025-04-12T18:01:04.723Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T18:04:35.993Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {A fundamental objective in quantum information science is to determine the cost in classical resources of simulating a particular quantum system. The classical simulation cost is quantified by the signaling dimension which specifies the minimum amount of classical communication needed to perfectly simulate a channel's input-output correlations when unlimited shared randomness is held between encoder and decoder. This paper provides a collection of device-independent tests that place lower and upper bounds on the signaling dimension of a channel. Among them, a single family of tests is shown to determine when a noisy classical channel can be simulated using an amount of communication strictly less than either its input or its output alphabet size. In addition, a family of eight signaling dimension witnesses is presented that completely characterize when any four-outcome measurement channel, such as a Bell measurement, can be simulated using one communication bit and shared randomness. Finally, we bound the signaling dimension for all partial replacer channels in d dimensions. The bounds are found to be tight for the special case of the erasure channel.},\\n bibtype = {article},\\n author = {Doolittle, Brian and Chitambar, Eric},\\n doi = {10.1103/PhysRevResearch.3.043073},\\n journal = {Physical Review Research},\\n number = {4}\\n}\",\"author_short\":[\"Doolittle,  B.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7c69caa1-840f-c0a7-6e05-336e130c43eb/Doolittle_2021_Certifying_the_classical_simulation_cost_of_a.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"doolittle-chitambar-certifyingtheclassicalsimulationcostofaquantumchannel-2021\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Hierarchy of multipartite correlations based on concentratable entanglement\",\"type\":\"article\",\"year\":\"2024\",\"volume\":\"6\",\"month\":\"4\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"0655f4a8-c093-34eb-84d3-c3c8da4331f4\",\"created\":\"2025-04-12T18:01:06.082Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T18:03:26.987Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Multipartite entanglement is one of the hallmarks of quantum mechanics and is central to quantum information processing. In this work we show that concentratable entanglement (CE), an operationally motivated entanglement measure, induces a hierarchy upon pure states from which different entanglement structures can be experimentally certified. In particular, we find that nearly all genuine multipartite entangled states can be verified through the CE. Interestingly, GHZ states prove to be far from maximally entangled according to this measure. Instead we find the exact maximal value and corresponding states for up to 18 qubits and show that these correspond to extremal quantum error correcting codes. The latter allows us to unravel a deep connection between CE and coding theory. Finally, our results also offer an alternative proof, on up to 31 qubits, that absolutely maximally entangled states do not exist.\",\"bibtype\":\"article\",\"author\":\"Schatzki, Louis and Liu, Guangkuo and Cerezo, M. and Chitambar, Eric\",\"doi\":\"10.1103/PhysRevResearch.6.023019\",\"journal\":\"Physical Review Research\",\"number\":\"2\",\"bibtex\":\"@article{\\n title = {Hierarchy of multipartite correlations based on concentratable entanglement},\\n type = {article},\\n year = {2024},\\n volume = {6},\\n month = {4},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {0655f4a8-c093-34eb-84d3-c3c8da4331f4},\\n created = {2025-04-12T18:01:06.082Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T18:03:26.987Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Multipartite entanglement is one of the hallmarks of quantum mechanics and is central to quantum information processing. In this work we show that concentratable entanglement (CE), an operationally motivated entanglement measure, induces a hierarchy upon pure states from which different entanglement structures can be experimentally certified. In particular, we find that nearly all genuine multipartite entangled states can be verified through the CE. Interestingly, GHZ states prove to be far from maximally entangled according to this measure. Instead we find the exact maximal value and corresponding states for up to 18 qubits and show that these correspond to extremal quantum error correcting codes. The latter allows us to unravel a deep connection between CE and coding theory. Finally, our results also offer an alternative proof, on up to 31 qubits, that absolutely maximally entangled states do not exist.},\\n bibtype = {article},\\n author = {Schatzki, Louis and Liu, Guangkuo and Cerezo, M. and Chitambar, Eric},\\n doi = {10.1103/PhysRevResearch.6.023019},\\n journal = {Physical Review Research},\\n number = {2}\\n}\",\"author_short\":[\"Schatzki,  L.\",\"Liu,  G.\",\"Cerezo,  M.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4e022833-6a0e-f161-59cc-919b761c4517/Schatzki_2024_Hierarchy_of_multipartite_correlations_based_o.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"schatzki-liu-cerezo-chitambar-hierarchyofmultipartitecorrelationsbasedonconcentratableentanglement-2024\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Incompatibility as a Resource for Programmable Quantum Instruments\",\"type\":\"article\",\"year\":\"2024\",\"volume\":\"5\",\"month\":\"1\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"37d28aa7-b884-3fd7-b908-383e76f00f66\",\"created\":\"2025-04-12T18:01:07.654Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T18:03:30.443Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Quantum instruments represent the most general type of quantum measurement, as they incorporate processes with both classical and quantum outputs. In many scenarios, it may be desirable to have some \\\"on-demand\\\"device that is capable of implementing one of many possible instruments whenever the experimenter desires. We refer to such objects as programmable instrument devices (PIDs), and this paper studies PIDs from a resource-theoretic perspective. A physically important class of PIDs are those that do not require quantum memories to implement, and these are naturally \\\"free\\\"in this resource theory. Additionally, these free objects correspond precisely to the class of unsteerable channel assemblages in the study of channel steering. The traditional notion of measurement incompatibility emerges as a resource in this theory since any PID controlling an incompatible family of instruments requires a quantum memory to build. We identify an incompatibility preorder between PIDs based on whether one can be transformed into another using processes that do not require additional quantum memories. Necessary and sufficient conditions are derived for when such transformations are possible based on how well certain guessing games can be played using a given PID. Ultimately our results provide an operational characterization of incompatibility, and they offer semi-device-independent tests for incompatibility in the most general types of quantum instruments.\",\"bibtype\":\"article\",\"author\":\"Ji, Kaiyuan and Chitambar, Eric\",\"doi\":\"10.1103/PRXQuantum.5.010340\",\"journal\":\"PRX Quantum\",\"number\":\"1\",\"bibtex\":\"@article{\\n title = {Incompatibility as a Resource for Programmable Quantum Instruments},\\n type = {article},\\n year = {2024},\\n volume = {5},\\n month = {1},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {37d28aa7-b884-3fd7-b908-383e76f00f66},\\n created = {2025-04-12T18:01:07.654Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T18:03:30.443Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Quantum instruments represent the most general type of quantum measurement, as they incorporate processes with both classical and quantum outputs. In many scenarios, it may be desirable to have some \\\"on-demand\\\"device that is capable of implementing one of many possible instruments whenever the experimenter desires. We refer to such objects as programmable instrument devices (PIDs), and this paper studies PIDs from a resource-theoretic perspective. A physically important class of PIDs are those that do not require quantum memories to implement, and these are naturally \\\"free\\\"in this resource theory. Additionally, these free objects correspond precisely to the class of unsteerable channel assemblages in the study of channel steering. The traditional notion of measurement incompatibility emerges as a resource in this theory since any PID controlling an incompatible family of instruments requires a quantum memory to build. We identify an incompatibility preorder between PIDs based on whether one can be transformed into another using processes that do not require additional quantum memories. Necessary and sufficient conditions are derived for when such transformations are possible based on how well certain guessing games can be played using a given PID. Ultimately our results provide an operational characterization of incompatibility, and they offer semi-device-independent tests for incompatibility in the most general types of quantum instruments.},\\n bibtype = {article},\\n author = {Ji, Kaiyuan and Chitambar, Eric},\\n doi = {10.1103/PRXQuantum.5.010340},\\n journal = {PRX Quantum},\\n number = {1}\\n}\",\"author_short\":[\"Ji,  K.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/20523456-3cc7-8b57-315b-4df63c3c476f/Ji_2024_Incompatibility_as_a_Resource_for_Programmable_Quant.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"ji-chitambar-incompatibilityasaresourceforprogrammablequantuminstruments-2024\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"The Round Complexity of Local Operations and Classical Communication (LOCC) in Random-Party Entanglement Distillation\",\"type\":\"article\",\"year\":\"2023\",\"volume\":\"7\",\"publisher\":\"Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften\",\"id\":\"08d505c5-be9f-3f5c-96ee-3822c9c0d860\",\"created\":\"2025-04-12T18:01:10.179Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T18:04:06.297Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"A powerful operational paradigm for distributed quantum information processing involves manipulating pre-shared entanglement by local operations and classical communication (LOCC). The LOCC round complexity of a given task describes how many rounds of classical communication are needed to complete the task. Despite some results separating one-round versus two-round protocols, very little is known about higher round complexities. In this paper, we revisit the task of one-shot random-party entanglement distillation as a way to highlight some interesting features of LOCC round complexity. We first show that for random-party distillation in three qubits, the number of communication rounds needed in an optimal protocol depends on the entanglement measure used; for the same fixed state some entanglement measures need only two rounds to maximize whereas others need an unbounded number of rounds. In doing so, we construct a family of LOCC instruments that require an unbounded number of rounds to implement. We then prove explicit tight lower bounds on the LOCC round number as a function of distillation success probability. Our calculations show that the original W-state random distillation protocol by Fortescue and Lo is essentially optimal in terms of round complexity.\",\"bibtype\":\"article\",\"author\":\"Liu, Guangkuo and George, Ian and Chitambar, Eric\",\"doi\":\"10.22331/Q-2023-09-07-1104\",\"journal\":\"Quantum\",\"bibtex\":\"@article{\\n title = {The Round Complexity of Local Operations and Classical Communication (LOCC) in Random-Party Entanglement Distillation},\\n type = {article},\\n year = {2023},\\n volume = {7},\\n publisher = {Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften},\\n id = {08d505c5-be9f-3f5c-96ee-3822c9c0d860},\\n created = {2025-04-12T18:01:10.179Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T18:04:06.297Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {A powerful operational paradigm for distributed quantum information processing involves manipulating pre-shared entanglement by local operations and classical communication (LOCC). The LOCC round complexity of a given task describes how many rounds of classical communication are needed to complete the task. Despite some results separating one-round versus two-round protocols, very little is known about higher round complexities. In this paper, we revisit the task of one-shot random-party entanglement distillation as a way to highlight some interesting features of LOCC round complexity. We first show that for random-party distillation in three qubits, the number of communication rounds needed in an optimal protocol depends on the entanglement measure used; for the same fixed state some entanglement measures need only two rounds to maximize whereas others need an unbounded number of rounds. In doing so, we construct a family of LOCC instruments that require an unbounded number of rounds to implement. We then prove explicit tight lower bounds on the LOCC round number as a function of distillation success probability. Our calculations show that the original W-state random distillation protocol by Fortescue and Lo is essentially optimal in terms of round complexity.},\\n bibtype = {article},\\n author = {Liu, Guangkuo and George, Ian and Chitambar, Eric},\\n doi = {10.22331/Q-2023-09-07-1104},\\n journal = {Quantum}\\n}\",\"author_short\":[\"Liu,  G.\",\"George,  I.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/07e6c3ed-8036-f62f-74b1-687e656c4af3/Liu_2023_The_Round_Complexity_of_Local_Operations_and_Classi.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"liu-george-chitambar-theroundcomplexityoflocaloperationsandclassicalcommunicationloccinrandompartyentanglementdistillation-2023\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Quantum Bell nonlocality as a form of entanglement\",\"type\":\"article\",\"year\":\"2021\",\"volume\":\"104\",\"month\":\"11\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"3149dae2-6486-3227-866c-8d53a9798d7b\",\"created\":\"2025-04-12T18:01:33.606Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T18:04:40.733Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Bell nonlocality describes a manifestation of quantum mechanics that cannot be explained by any local hidden variable model. Its origin lies in the nature of quantum entanglement, although understanding the precise relationship between nonlocality and entanglement has been a notorious open problem. In this paper, we develop a dynamical framework in which quantum Bell nonlocality emerges as a special form of entanglement and both are unified as resources under local operations and classical communication (LOCC). Our framework is built on the notion of classical and quantum processes, which are defined as channels that map elements between specific intervals in space and time. Entanglement is identified as a process that cannot be generated by LOCC while Bell nonlocality is the subset of these processes that have an instantaneous input-to-output delay time. LOCC preprocessing is a natural set of free operations in this theory, thereby providing previous nonlocality activation results a clear resource-theoretic foundation. We provide a systematic method to quantify the Bell nonlocality of a bipartite quantum channel. It is shown that both the relative entropy and the max relative entropy of nonlocality are nonadditive for a family of bipartite classical channels. This family includes the channel obtained when using the singlet state to maximally violate the CHSH inequality. We also find that the regularized relative entropy of Bell nonlocality provides an upper bound on the asymptotic rate of converting (i.e., simulating) many copies of one classical instantaneous resource to another.\",\"bibtype\":\"article\",\"author\":\"Chitambar, Eric and Gour, Gilad and Sengupta, Kuntal and Zibakhsh, Rana\",\"doi\":\"10.1103/PhysRevA.104.052208\",\"journal\":\"Physical Review A\",\"number\":\"5\",\"bibtex\":\"@article{\\n title = {Quantum Bell nonlocality as a form of entanglement},\\n type = {article},\\n year = {2021},\\n volume = {104},\\n month = {11},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {3149dae2-6486-3227-866c-8d53a9798d7b},\\n created = {2025-04-12T18:01:33.606Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T18:04:40.733Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Bell nonlocality describes a manifestation of quantum mechanics that cannot be explained by any local hidden variable model. Its origin lies in the nature of quantum entanglement, although understanding the precise relationship between nonlocality and entanglement has been a notorious open problem. In this paper, we develop a dynamical framework in which quantum Bell nonlocality emerges as a special form of entanglement and both are unified as resources under local operations and classical communication (LOCC). Our framework is built on the notion of classical and quantum processes, which are defined as channels that map elements between specific intervals in space and time. Entanglement is identified as a process that cannot be generated by LOCC while Bell nonlocality is the subset of these processes that have an instantaneous input-to-output delay time. LOCC preprocessing is a natural set of free operations in this theory, thereby providing previous nonlocality activation results a clear resource-theoretic foundation. We provide a systematic method to quantify the Bell nonlocality of a bipartite quantum channel. It is shown that both the relative entropy and the max relative entropy of nonlocality are nonadditive for a family of bipartite classical channels. This family includes the channel obtained when using the singlet state to maximally violate the CHSH inequality. We also find that the regularized relative entropy of Bell nonlocality provides an upper bound on the asymptotic rate of converting (i.e., simulating) many copies of one classical instantaneous resource to another.},\\n bibtype = {article},\\n author = {Chitambar, Eric and Gour, Gilad and Sengupta, Kuntal and Zibakhsh, Rana},\\n doi = {10.1103/PhysRevA.104.052208},\\n journal = {Physical Review A},\\n number = {5}\\n}\",\"author_short\":[\"Chitambar,  E.\",\"Gour,  G.\",\"Sengupta,  K.\",\"Zibakhsh,  R.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/51bedf13-11b9-3acd-7415-609973fc8dbf/Chitambar_2021_Quantum_Bell_nonlocality_as_a_form_of_entangl.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"chitambar-gour-sengupta-zibakhsh-quantumbellnonlocalityasaformofentanglement-2021\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Entanglement of assistance in three-qubit systems\",\"type\":\"article\",\"year\":\"2021\",\"volume\":\"103\",\"month\":\"3\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"30a20f92-add7-389f-b1cd-e8064e0fe4a1\",\"created\":\"2025-04-12T18:06:35.114Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-12T18:06:50.194Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"The entanglement of assistance quantifies the amount of entanglement that can be concentrated among a group of spatially separated parties using the assistance of some auxiliary system. In this paper we study the entanglement of assistance in the simplest scenario of three qubits. We consider how much entanglement is lost when the helper party becomes uncoupled by local measurement and classical communication. For three-qubit pure states, it is found that lossless decoupling is always possible when entanglement is quantified by the maximum probability of locally generating a Bell state. However, with respect to most other entanglement measures, such as concurrence and entanglement entropy, a lossless decoupling of the helper is possible only for a special family of states that we fully characterize.\",\"bibtype\":\"article\",\"author\":\"Pollock, Klee and Wang, Ge and Chitambar, Eric\",\"doi\":\"10.1103/PhysRevA.103.032428\",\"journal\":\"Physical Review A\",\"number\":\"3\",\"bibtex\":\"@article{\\n title = {Entanglement of assistance in three-qubit systems},\\n type = {article},\\n year = {2021},\\n volume = {103},\\n month = {3},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {30a20f92-add7-389f-b1cd-e8064e0fe4a1},\\n created = {2025-04-12T18:06:35.114Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-12T18:06:50.194Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {The entanglement of assistance quantifies the amount of entanglement that can be concentrated among a group of spatially separated parties using the assistance of some auxiliary system. In this paper we study the entanglement of assistance in the simplest scenario of three qubits. We consider how much entanglement is lost when the helper party becomes uncoupled by local measurement and classical communication. For three-qubit pure states, it is found that lossless decoupling is always possible when entanglement is quantified by the maximum probability of locally generating a Bell state. However, with respect to most other entanglement measures, such as concurrence and entanglement entropy, a lossless decoupling of the helper is possible only for a special family of states that we fully characterize.},\\n bibtype = {article},\\n author = {Pollock, Klee and Wang, Ge and Chitambar, Eric},\\n doi = {10.1103/PhysRevA.103.032428},\\n journal = {Physical Review A},\\n number = {3}\\n}\",\"author_short\":[\"Pollock,  K.\",\"Wang,  G.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7e45f887-2932-9525-20f6-bc5ce04d875b/Pollock_2021_Entanglement_of_assistance_in_three_qubit_sys_1.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"pollock-wang-chitambar-entanglementofassistanceinthreequbitsystems-2021\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Tensor rank and other multipartite entanglement measures of graph states\",\"type\":\"article\",\"year\":\"2024\",\"volume\":\"110\",\"month\":\"9\",\"publisher\":\"American Physical Society\",\"day\":\"1\",\"id\":\"d0f4460c-c596-3010-a7e0-e5cf875cebc3\",\"created\":\"2025-04-13T16:59:49.510Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-13T16:59:58.743Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Graph states play an important role in quantum information theory through their connection to measurement-based computing and error correction. Prior work revealed elegant connections between the graph structure of these states and their multipartite entanglement. We continue this line of investigation by identifying additional entanglement properties for certain types of graph states. From the perspective of tensor theory, we tighten both upper and lower bounds on the tensor rank of odd ring states (|R2n+1)) to read 2n+1≤rank(|R2n+1))≤3×2n-1. Next we show that several multipartite extensions of bipartite entanglement measures are dichotomous for graph states based on the connectivity of the corresponding graph. Finally, we give a simple graph rule for computing the n-tangle τn.\",\"bibtype\":\"article\",\"author\":\"Schatzki, Louis and Ma, Linjian and Solomonik, Edgar and Chitambar, Eric\",\"doi\":\"10.1103/PhysRevA.110.032409\",\"journal\":\"Physical Review A\",\"number\":\"3\",\"bibtex\":\"@article{\\n title = {Tensor rank and other multipartite entanglement measures of graph states},\\n type = {article},\\n year = {2024},\\n volume = {110},\\n month = {9},\\n publisher = {American Physical Society},\\n day = {1},\\n id = {d0f4460c-c596-3010-a7e0-e5cf875cebc3},\\n created = {2025-04-13T16:59:49.510Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-13T16:59:58.743Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Graph states play an important role in quantum information theory through their connection to measurement-based computing and error correction. Prior work revealed elegant connections between the graph structure of these states and their multipartite entanglement. We continue this line of investigation by identifying additional entanglement properties for certain types of graph states. From the perspective of tensor theory, we tighten both upper and lower bounds on the tensor rank of odd ring states (|R2n+1)) to read 2n+1≤rank(|R2n+1))≤3×2n-1. Next we show that several multipartite extensions of bipartite entanglement measures are dichotomous for graph states based on the connectivity of the corresponding graph. Finally, we give a simple graph rule for computing the n-tangle τn.},\\n bibtype = {article},\\n author = {Schatzki, Louis and Ma, Linjian and Solomonik, Edgar and Chitambar, Eric},\\n doi = {10.1103/PhysRevA.110.032409},\\n journal = {Physical Review A},\\n number = {3}\\n}\",\"author_short\":[\"Schatzki,  L.\",\"Ma,  L.\",\"Solomonik,  E.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/527b3d70-9a90-75ef-56ba-4f27f2b7cc97/Schatzki_2024_Tensor_rank_and_other_multipartite_entanglemen.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"schatzki-ma-solomonik-chitambar-tensorrankandothermultipartiteentanglementmeasuresofgraphstates-2024\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"Dynamical resource theory of quantum coherence\",\"type\":\"article\",\"year\":\"2020\",\"volume\":\"2\",\"month\":\"6\",\"publisher\":\"American Physical Society\",\"day\":\"8\",\"id\":\"9b81b5f6-a9d1-393b-a18b-6671b35346e4\",\"created\":\"2025-04-13T17:02:45.760Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-04-13T17:03:02.550Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"Decoherence is all around us. Every quantum system that interacts with the environment is doomed to decohere. While preserving quantum coherence is a major challenge faced in quantum technologies, the potential benefits for information processing are very promising since coherence can lead to various operational advantages, such as in quantum algorithms. Hence, much work has been devoted in recent years to quantify the coherence present in a system. In the present paper, we formulate the quantum resource theory of dynamical coherence. The underlying physical principle we follow is that the free dynamical objects are those that neither store nor output coherence. This leads us to identify classical channels as the free elements in this theory. Consequently, even the quantum identity channel is not free as all physical systems undergo decoherence and hence, the preservation of coherence should be considered a resource. The maximally coherent channel is then the quantum Fourier transform because of its abillity to preserve entanglement and generate maximal coherence from nothing. In our work, we introduce four different types of free superchannels (analogous to MIO, DIO, IO, and SIO) and discuss in detail two of them, namely, dephasing-covariant incoherent superchannels (DISC), maximally incoherent superchannels (MISC). The latter consists of all superchannels that do not generate non-classical channels from classical ones. We quantify dynamical coherence using channel-divergence-based monotones for MISC and DISC. We show that some of these monotones have operational interpretations as the exact, the approximate, and the liberal coherence cost of a quantum channel. Moreover, we prove that the liberal asymptotic cost of a channel is equal to a new type of regularized relative entropy. Finally, we show that the conversion distance between two channels under MISC and DISC can be computed using a semidefinite program (SDP).\",\"bibtype\":\"article\",\"author\":\"Saxena, Gaurav and Chitambar, Eric and Gour, Gilad\",\"doi\":\"10.1103/PhysRevResearch.2.023298\",\"journal\":\"Physical Review Research\",\"number\":\"2\",\"bibtex\":\"@article{\\n title = {Dynamical resource theory of quantum coherence},\\n type = {article},\\n year = {2020},\\n volume = {2},\\n month = {6},\\n publisher = {American Physical Society},\\n day = {8},\\n id = {9b81b5f6-a9d1-393b-a18b-6671b35346e4},\\n created = {2025-04-13T17:02:45.760Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-04-13T17:03:02.550Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {Decoherence is all around us. Every quantum system that interacts with the environment is doomed to decohere. While preserving quantum coherence is a major challenge faced in quantum technologies, the potential benefits for information processing are very promising since coherence can lead to various operational advantages, such as in quantum algorithms. Hence, much work has been devoted in recent years to quantify the coherence present in a system. In the present paper, we formulate the quantum resource theory of dynamical coherence. The underlying physical principle we follow is that the free dynamical objects are those that neither store nor output coherence. This leads us to identify classical channels as the free elements in this theory. Consequently, even the quantum identity channel is not free as all physical systems undergo decoherence and hence, the preservation of coherence should be considered a resource. The maximally coherent channel is then the quantum Fourier transform because of its abillity to preserve entanglement and generate maximal coherence from nothing. In our work, we introduce four different types of free superchannels (analogous to MIO, DIO, IO, and SIO) and discuss in detail two of them, namely, dephasing-covariant incoherent superchannels (DISC), maximally incoherent superchannels (MISC). The latter consists of all superchannels that do not generate non-classical channels from classical ones. We quantify dynamical coherence using channel-divergence-based monotones for MISC and DISC. We show that some of these monotones have operational interpretations as the exact, the approximate, and the liberal coherence cost of a quantum channel. Moreover, we prove that the liberal asymptotic cost of a channel is equal to a new type of regularized relative entropy. Finally, we show that the conversion distance between two channels under MISC and DISC can be computed using a semidefinite program (SDP).},\\n bibtype = {article},\\n author = {Saxena, Gaurav and Chitambar, Eric and Gour, Gilad},\\n doi = {10.1103/PhysRevResearch.2.023298},\\n journal = {Physical Review Research},\\n number = {2}\\n}\",\"author_short\":[\"Saxena,  G.\",\"Chitambar,  E.\",\"Gour,  G.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/354277b5-1b25-9c29-0403-b02eaaa899ab/Saxena_2020_Dynamical_resource_theory_of_quantum_coherence.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"saxena-chitambar-gour-dynamicalresourcetheoryofquantumcoherence-2020\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":5,\"html\":\"\"},{\"title\":\"Random Distillation Protocols in Long Baseline Telescopy\",\"type\":\"article\",\"year\":\"2025\",\"volume\":\"134\",\"month\":\"5\",\"publisher\":\"American Physical Society\",\"day\":\"2\",\"id\":\"19d57ebf-f977-3374-bb32-888215d22e47\",\"created\":\"2025-05-13T13:04:04.890Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-05-13T13:04:19.198Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"abstract\":\"In quantum-enhanced astronomical imaging, multiple distant apertures work together by utilizing quantum resources distributed from a central server. Our findings suggest that preprocessing the stellar light received by all telescopes can improve imaging performance without increasing resource consumption. The preprocessing leverages weak quantum measurements and modifies random-party entanglement distillation protocols from quantum information science. Intuitively, this approach allows us to collapse the stellar light that is originally coherent between all telescopes to one pair of telescopes with probability arbitrarily close to one. The central server can then distribute entanglement solely to the pair of telescopes receiving a photon, thereby enhancing the efficiency of resource utilization. We discuss two types of resources that benefit from this preprocessing: shared entanglement and a shared reference frame.\",\"bibtype\":\"article\",\"author\":\"Wang, Yunkai and Chitambar, Eric\",\"doi\":\"10.1103/PhysRevLett.134.170801\",\"journal\":\"Physical Review Letters\",\"number\":\"17\",\"bibtex\":\"@article{\\n title = {Random Distillation Protocols in Long Baseline Telescopy},\\n type = {article},\\n year = {2025},\\n volume = {134},\\n month = {5},\\n publisher = {American Physical Society},\\n day = {2},\\n id = {19d57ebf-f977-3374-bb32-888215d22e47},\\n created = {2025-05-13T13:04:04.890Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-05-13T13:04:19.198Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n abstract = {In quantum-enhanced astronomical imaging, multiple distant apertures work together by utilizing quantum resources distributed from a central server. Our findings suggest that preprocessing the stellar light received by all telescopes can improve imaging performance without increasing resource consumption. The preprocessing leverages weak quantum measurements and modifies random-party entanglement distillation protocols from quantum information science. Intuitively, this approach allows us to collapse the stellar light that is originally coherent between all telescopes to one pair of telescopes with probability arbitrarily close to one. The central server can then distribute entanglement solely to the pair of telescopes receiving a photon, thereby enhancing the efficiency of resource utilization. We discuss two types of resources that benefit from this preprocessing: shared entanglement and a shared reference frame.},\\n bibtype = {article},\\n author = {Wang, Yunkai and Chitambar, Eric},\\n doi = {10.1103/PhysRevLett.134.170801},\\n journal = {Physical Review Letters},\\n number = {17}\\n}\",\"author_short\":[\"Wang,  Y.\",\"Chitambar,  E.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/03b6b4b0-2c7d-c0f7-655e-32a10b1dccbf/Wang_2025_Random_Distillation_Protocols_in_Long_Baseline_T_1.pdf.pdf\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"wang-chitambar-randomdistillationprotocolsinlongbaselinetelescopy-2025\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"},{\"title\":\"No-Go Theorems for Universal Entanglement Purification\",\"type\":\"article\",\"year\":\"2025\",\"pages\":\"190803\",\"volume\":\"134\",\"websites\":\"https://link.aps.org/doi/10.1103/PhysRevLett.134.190803\",\"month\":\"5\",\"day\":\"13\",\"id\":\"10898382-50d4-3de6-8710-9901a12f1cee\",\"created\":\"2025-05-14T14:45:58.217Z\",\"file_attached\":\"true\",\"profile_id\":\"889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"last_modified\":\"2025-05-14T14:46:05.189Z\",\"read\":false,\"starred\":false,\"authored\":\"true\",\"confirmed\":false,\"hidden\":false,\"private_publication\":false,\"bibtype\":\"article\",\"author\":\"Zang, Allen and Chen, Xinan and Chitambar, Eric and Suchara, Martin and Zhong, Tian\",\"doi\":\"10.1103/PhysRevLett.134.190803\",\"journal\":\"Physical Review Letters\",\"number\":\"19\",\"bibtex\":\"@article{\\n title = {No-Go Theorems for Universal Entanglement Purification},\\n type = {article},\\n year = {2025},\\n pages = {190803},\\n volume = {134},\\n websites = {https://link.aps.org/doi/10.1103/PhysRevLett.134.190803},\\n month = {5},\\n day = {13},\\n id = {10898382-50d4-3de6-8710-9901a12f1cee},\\n created = {2025-05-14T14:45:58.217Z},\\n file_attached = {true},\\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\\n last_modified = {2025-05-14T14:46:05.189Z},\\n read = {false},\\n starred = {false},\\n authored = {true},\\n confirmed = {false},\\n hidden = {false},\\n private_publication = {false},\\n bibtype = {article},\\n author = {Zang, Allen and Chen, Xinan and Chitambar, Eric and Suchara, Martin and Zhong, Tian},\\n doi = {10.1103/PhysRevLett.134.190803},\\n journal = {Physical Review Letters},\\n number = {19}\\n}\",\"author_short\":[\"Zang,  A.\",\"Chen,  X.\",\"Chitambar,  E.\",\"Suchara,  M.\",\"Zhong,  T.\"],\"urls\":{\"Paper\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/6bbfbbda-957d-437b-4a5e-eb3aac99f257/Zang_2025_No_Go_Theorems_for_Universal_Entanglement_Purifica.pdf.pdf\",\"Website\":\"https://link.aps.org/doi/10.1103/PhysRevLett.134.190803\"},\"biburl\":\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0\",\"bibbaseid\":\"zang-chen-chitambar-suchara-zhong-nogotheoremsforuniversalentanglementpurification-2025\",\"role\":\"author\",\"metadata\":{\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\"downloads\":0,\"html\":\"\"}],\n      metadata: {\"owner\":\"chitambar,  e\",\"authorlinks\":{\"chitambar,  e\":\"https://quantum-entangled.ece.illinois.edu/research/\"}},\n      ownerID: \"o2ejS6RYLpGPuopad\"\n    };\n  </script>\n\n  <script type=\"text/javascript\">\n  var site$;\n  if (typeof $ != 'undefined') {\n    console.log('existing jquery: storing and then restoring');\n    site$ = $;\n    $ = null;\n  }\n  </script>\n\n  <script src=\"https://ajax.googleapis.com/ajax/libs/jquery/2.2.4/jquery.min.js\">\n  </script>\n  <script type=\"text/javascript\">\n  if (site$) {\n    console.log('existing jquery: avoiding conflict and restoring');\n    bb$ = $.noConflict(true);\n    $ = site$;\n  } else {\n    bb$ = $;\n  }\n  </script>\n\n  <script src=\"//bibbase.org/js/bibbase.min.js\"\n          type=\"text/javascript\">\n  </script>\n\n  <script type=\"text/javascript\"\n          src=\"https://cdnjs.cloudflare.com/ajax/libs/mathjax/2.7.1/MathJax.js?config=TeX-AMS-MML_HTMLorMML\">\n  </script>\n  <script type=\"text/x-mathjax-config\">\n    MathJax.Hub.Config({tex2jax: {inlineMath: [['$','$'], ['\\\\(','\\\\)']]},\n                        skipTags: [\"body\"],\n                        processClass: \"bibbase_paper\"});\n  </script>\n\n  <style>\n  @media print {\n    .dontprint {\n        display: none !important;\n    }\n\n  .bibbase_group {\n    background-color: #E0E0E0;\n    font-style: italic;\n    font-size: larger;\n    text-shadow: 0px 0px 3px #FFFFFF;\n    border-radius: 4px 4px 4px 4px;\n    -moz-border-radius: 4px 4px 4px 4px;\n    -webkit-border-radius: 4px;\n    padding: 5px 40px 5px;\n    margin-top: 10px;\n    margin-bottom: 5px;\n    cursor: pointer;\n  }\n\n  .bibbase_paper {\n    margin-bottom: 5px;\n  }\n\n  }\n  </style>\n\n  \n  <div style=\"float: right; margin-right: 10px; margin-top: 10px; text-align: right; font-size: 12px\">\n    generated by\n    <a href=\"//bibbase.org\"\n       onclick=\"trackOutboundLink('bibbase', 'logo clicked', window.location.href, '//bibbase.org'); return false;\">\n      <img src=\"//bibbase.org/img/logo.svg\"\n           style=\"vertical-align: middle; margin-left: 3px; height: 16px;\"/\n           alt=\"bibbase.org\"\n           title=\"BibBase – The easiest way to maintain your publications page.\"\n        ></a>\n    \n  </div>\n  \n\n  <div id=\"bibbase_header\" class=\"dontprint\" style=\"\">\n\n    <ul class=\"nav nav-pills\" style=\"margin: 0px;\">\n\n      <li class=\"dropdown\" id=\"groupby_dropdown\">\n      <a class=\"dropdown-toggle\"\n         data-toggle=\"dropdown\"\n         href=\"#\">\n          Group by\n          <b class=\"caret\"></b>\n      </a>\n      <ul class=\"dropdown-menu\">\n        <li class=\"groupby year\"><a onclick=\"groupby('year')\">\n            Year</a>\n        </li>\n        <li class=\"groupby author\"><a onclick=\"groupby('author_short')\">\n            Author</a>\n        </li>\n        <li class=\"groupby type\"><a onclick=\"groupby('type')\">\n            Type</a>\n        </li>\n        <li class=\"groupby keyword\"><a onclick=\"groupby('keyword')\">\n            Keyword</a>\n        </li>\n        <li class=\"groupby downloads\"><a onclick=\"groupby('downloads')\">\n            Downloads</a>\n        </li>\n      </ul>\n      </li>\n\n\n      <li class=\"dropdown\" id=\"menu_dropdown\">\n      <a class=\"dropdown-toggle\"\n         data-toggle=\"dropdown\"\n         href=\"#\" alt=\"controls\">\n          <i class=\"fa fa-reorder\" alt=\"controls\"></i>\n          <b class=\"caret\"></b>\n      </a>\n      <ul class=\"dropdown-menu\">\n        <li>\n          <a onclick=\"toggleAll()\">\n            <i class=\"fa fa-chevron-down fa-fw\"></i> Expand/Collapse All\n          </a>\n        </li>\n        <li>\n          <a download=\"all.bib\" href=\"data:text/bibtex;base64,@article{
 title = {Dephasing-covariant operations enable asymptotic reversibility of quantum resources},
 type = {article},
 year = {2018},
 volume = {97},
 id = {151c3e2c-da77-395f-ae97-e6ad45abcd64},
 created = {2020-08-20T19:55:39.601Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.601Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2018 American Physical Society. We study the power of dephasing-covariant operations in the resource theories of coherence and entanglement. These are quantum operations whose actions commute with a projective measurement. In the resource theory of coherence, we find that any two states are asymptotically interconvertible under dephasing-covariant operations. This provides a rare example of a resource theory in which asymptotic reversibility can be attained without needing the maximal set of resource nongenerating operations. When extended to the resource theory of entanglement, the resultant operations share similarities with local operations and classical communication, such as prohibiting the increase of all Rényi α-entropies of entanglement under pure-state transformations. However, we show these operations are still strong enough to enable asymptotic reversibility between any two maximally correlated mixed states, even in the multipartite setting.},
 bibtype = {article},
 author = {Chitambar, E.},
 doi = {10.1103/PhysRevA.97.050301},
 journal = {Physical Review A},
 number = {5}
}

@article{
 title = {Quantum correlations in high-dimensional states of high symmetry},
 type = {article},
 year = {2012},
 volume = {86},
 id = {baa02e1e-43b2-3dd1-a385-61bfb09db026},
 created = {2020-08-20T19:55:39.602Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.602Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {In this article, we investigate how quantum correlations behave for the so-called Werner and pseudopure families of states. The latter refers to states formed by mixing any pure state with the totally mixed state. We derive closed expressions for the quantum discord and the relative entropy of quantumness for these families of states. For Werner states, the classical correlations are seen to vanish in high dimensions while the amount of quantum correlations remains bounded. For pseudopure states, nearly the opposite effect is observed, with both the quantum and classical correlations growing without bound as the dimension increases and only as the system becomes more entangled. In light of our calculations, we discuss how Werner states could play a role as a quantum one-time pad in cryptographic tasks and, along with isotropic states, could function as a quantum memory device designed to maximize the uncertainty tradeoff between noncommuting measurements on the individual subsystems. © 2012 American Physical Society.},
 bibtype = {article},
 author = {Chitambar, E.},
 doi = {10.1103/PhysRevA.86.032110},
 journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
 number = {3}
}

@article{
 title = {Local quantum transformations requiring infinite rounds of classical communication},
 type = {article},
 year = {2011},
 volume = {107},
 id = {04baa759-4863-3a0b-9c40-df596776fcb3},
 created = {2020-08-20T19:55:39.642Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.642Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {In this Letter, we investigate the number of measurement and communication rounds needed to implement certain tasks by local quantum operations and classical communication (LOCC), a relatively unexplored topic. To demonstrate the possible strong dependence on the round number, we consider the problem of converting three-qubit entanglement into two-qubit form, specifically in the random distillation setting of. We find that the number of LOCC rounds needed for a transformation can depend on the amount of entanglement distilled. In fact, for a wide range of transformations, the required number of rounds is infinite (unbounded). This represents the first concrete example of a task needing an infinite number of rounds to implement. © 2011 American Physical Society.},
 bibtype = {article},
 author = {Chitambar, E.},
 doi = {10.1103/PhysRevLett.107.190502},
 journal = {Physical Review Letters},
 number = {19}
}

@article{
 title = {Bounds on Instantaneous Nonlocal Quantum Computation},
 type = {article},
 year = {2020},
 keywords = {Quantum entanglement,quantum computing,teleportation},
 volume = {66},
 id = {f1f63484-2a06-357f-9ed5-e7abb9843e18},
 created = {2020-08-20T19:55:39.652Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.652Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 1963-2012 IEEE. Instantaneous nonlocal quantum computation refers to a process in which spacelike separated parties simulate a nonlocal quantum operation on their joint systems through the consumption of pre-shared entanglement. To prevent a violation of causality, this simulation succeeds up to local errors that can only be corrected after the parties communicate classically with one another. However, this communication is non-interactive, and it involves just the broadcasting of local measurement outcomes. We refer to this operational paradigm as local operations and broadcast communication (LOBC) to distinguish it from the standard local operations and (interactive) classical communication (LOCC). In this paper, we show that an arbitrary two-qubit gate can be implemented by LOBC with $\epsilon $ -error using $O(\log (1/\epsilon))$ entangled bits (ebits). This offers an exponential improvement over the best known two-qubit protocols, whose ebit costs behave as $O(1/\epsilon)$. We also consider the family of binary controlled gates on dimensions $d_A\otimes d_B$. We find that any hermitian gate of this form can be implemented by LOBC using a single shared ebit. In sharp contrast, a lower bound of $\log d_B$ ebits is shown in the case of generic (i.e. non-hermitian) gates from this family, even when $d_A=2$. This demonstrates an unbounded gap between the entanglement costs of LOCC and LOBC gate implementation. Whereas previous lower bounds on the entanglement cost for instantaneous nonlocal computation restrict the minimum dimension of the needed entanglement, we bound its entanglement entropy. To our knowledge this is the first such lower bound of its kind.},
 bibtype = {article},
 author = {Gonzales, A. and Chitambar, E.},
 doi = {10.1109/TIT.2019.2950190},
 journal = {IEEE Transactions on Information Theory},
 number = {5}
}

@article{
 title = {The zero-error entanglement cost is highly non-additive},
 type = {article},
 year = {2019},
 volume = {60},
 id = {fe105007-3da1-3889-b174-c572ef813619},
 created = {2020-08-20T19:55:39.682Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.682Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2019 Author(s). The Schmidt number is an entanglement measure whose logarithm quantifies the zero-error entanglement cost of generating a given quantum state using local operations and classical communication. In this paper, we show that the Schmidt number is highly nonmultiplicative in the sense that for any integer n, there exist states whose Schmidt number remains constant when taking n copies of the given state. These states also provide a rare instance in which the regularized zero-error entanglement cost can be computed exactly. We then explore the question of increasing the Schmidt number by quantum operations. We describe a class of bipartite quantum operations that preserve the Schmidt number for pure state transformations, and yet they can increase the Schmidt number by an arbitrarily large amount when generating mixed states. Our results are obtained by making connections to the resource theory of quantum coherence and generalizing the class of dephasing-covariant incoherent operations to the bipartite setting.},
 bibtype = {article},
 author = {Yue, Q. and Chitambar, E.},
 doi = {10.1063/1.5087815},
 journal = {Journal of Mathematical Physics},
 number = {11}
}

@article{
 title = {Quantum resource theories},
 type = {article},
 year = {2019},
 volume = {91},
 id = {477ef01c-0b7c-3d78-8f24-7203f9ec3770},
 created = {2020-08-20T19:55:39.697Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.697Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2019 American Physical Society. Quantum resource theories (QRTs) offer a highly versatile and powerful framework for studying different phenomena in quantum physics. From quantum entanglement to quantum computation, resource theories can be used to quantify a desirable quantum effect, develop new protocols for its detection, and identify processes that optimize its use for a given application. Particularly, QRTs have revolutionized the way we think about familiar properties of physical systems such as entanglement, elevating them from being just interesting fundamental phenomena to being useful in performing practical tasks. The basic methodology of a general QRT involves partitioning all quantum states into two groups, one consisting of free states and the other consisting of resource states. Accompanying the set of free states is a collection of free quantum operations arising from natural restrictions placed on the physical system, restrictions that force the free operations to act invariantly on the set of free states. The QRT then studies what information processing tasks become possible using the restricted operations. Despite the large degree of freedom in how one defines the free states and free operations, unexpected similarities emerge among different QRTs in terms of resource measures and resource convertibility. As a result, objects that appear quite distinct on the surface, such as entanglement and quantum reference frames, appear to have great similarity on a deeper structural level. This article reviews the general framework of a quantum resource theory, focusing on common structural features, operational tasks, and resource measures. To illustrate these concepts, an overview is provided on some of the more commonly studied QRTs in the literature.},
 bibtype = {article},
 author = {Chitambar, E. and Gour, G.},
 doi = {10.1103/RevModPhys.91.025001},
 journal = {Reviews of Modern Physics},
 number = {2}
}

@article{
 title = {Comparing coherence and entanglement under resource non-generating unitary transformations},
 type = {article},
 year = {2018},
 keywords = {cohering power,quantum coherence,quantum entanglement,quantum information},
 volume = {51},
 id = {f7bb0eaf-f4d5-3f1e-a28b-09e0911ac99d},
 created = {2020-08-20T19:55:39.720Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.720Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2018 IOP Publishing Ltd. Quantum coherence is a fundamental property of quantum systems that can be studied within the framework of a quantum resource theory. From this resource-theoretic approach, many similarities emerge between coherence and quantum entanglement, the latter being another prominent quantum resource. In this paper, we study the relationship between coherence and entanglement from the perspective of resource loss/gain by unitary dynamics. Specifically we consider how much coherence can be either generated or destroyed on a bipartite system when the action is restricted to local unitary (LU) operations. For pure states, we find that the relative entropy of entanglement and the robustness of entanglement provide tight lower bounds on the amount of coherence that can be destroyed by LUs, as measured by the relative entropy and measures of coherence, respectively. This provides new operational interpretations of the entanglement entropy and robustness of entanglement in pure states as the minimal amount of coherence that persists when the system is subjected to LU transformations. We then study the amount of bipartite pure entanglement that can be either maximized or minimized when the action is restricted to a global incoherent operation. For two-qubit pure states, maximum and minimum are shown in terms of coefficients of given state with incoherent basis. Finally we consider a generalized version of the recently introduced CCP of a quantum channel.},
 bibtype = {article},
 author = {Takahashi, M. and Chitambar, E.},
 doi = {10.1088/1751-8121/aacc5c},
 journal = {Journal of Physics A: Mathematical and Theoretical},
 number = {41}
}

@article{
 title = {More nonlocality with less entanglement in Clauser-Horne-Shimony-Holt experiments using inefficient detectors},
 type = {article},
 year = {2018},
 volume = {97},
 id = {9f896e13-50f7-3da3-9e13-06a686ccbcc6},
 created = {2020-08-20T19:55:39.738Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.738Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2018 American Physical Society. It is well-known that in certain scenarios weakly entangled states can generate stronger nonlocal effects than their maximally entangled counterparts. In this paper, we consider violations of the Clauser-Horne-Shimony-Holt (CHSH) inequality when one party has inefficient detectors, a scenario known as an asymmetric Bell experiment. For any fixed detection efficiency, we derive a simple upper bound on the entanglement needed to violate the inequality by more than some specified amount κ≥0. When κ=0, the amount of entanglement in all states violating the inequality goes to zero as the detection efficiency approaches 50% from above. We finally consider the scenario in which detection inefficiency arises for only one choice of local measurement. In this case, it is shown that the CHSH inequality can always be violated for any nonzero detection efficiency and any choice of noncommuting measurements.},
 bibtype = {article},
 author = {Dilley, D. and Chitambar, E.},
 doi = {10.1103/PhysRevA.97.062313},
 journal = {Physical Review A},
 number = {6}
}

@article{
 title = {Round complexity in the local transformations of quantum and classical states},
 type = {article},
 year = {2017},
 volume = {8},
 id = {33eb12e6-a036-3823-afbc-f9af47594bcc},
 created = {2020-08-20T19:55:39.761Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.761Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2017 The Author(s). In distributed quantum and classical information processing, spatially separated parties operate locally on their respective subsystems, but coordinate their actions through multiple exchanges of public communication. With interaction, the parties can perform more tasks. But how the exact number and order of exchanges enhances their operational capabilities is not well understood. Here we consider the minimum number of communication rounds needed to perform the locality-constrained tasks of entanglement transformation and its classical analog of secrecy manipulation. We provide an explicit construction of both quantum and classical state transformations which, for any given r, can be achieved using r rounds of classical communication exchanges, but no fewer. To show this, we build on the common structure underlying both resource theories of quantum entanglement and classical secret key. Our results reveal that highly complex communication protocols are indeed necessary to fully harness the information-theoretic resources contained in general quantum and classical states.},
 bibtype = {article},
 author = {Chitambar, E. and Hsieh, M.-H.},
 doi = {10.1038/s41467-017-01887-5},
 journal = {Nature Communications},
 number = {1}
}

@article{
 title = {Comparison of incoherent operations and measures of coherence},
 type = {article},
 year = {2016},
 volume = {94},
 id = {4a0d2efa-8608-36a8-bbe3-55558cb82f54},
 created = {2020-08-20T19:55:39.782Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.782Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2016 American Physical Society. A resource theory of quantum coherence attempts to characterize the quantum coherence that exists in a given quantum system. Many different approaches to a resource theory of coherence have recently been proposed, with their differences lying primarily in the identification of "free" or "incoherent" operations. In this article, we compare a number of these operational classes. In particular, the recently introduced class of dephasing-covariant operations is analyzed, and we characterize the Kraus operators of such maps. A number of coherence measures are introduced based on relative Rényi entropies, and we study incoherent state transformations under different operational classes. In particular, we show that the incoherent Schmidt rank can be increased arbitrarily large by certain noncoherence generating operations. The distinction between asymmetry-based versus basis-dependent notions of coherence theory is clarified, and we further develop the resource theory of N asymmetry, where N is the group of all diagonal incoherent unitaries.},
 bibtype = {article},
 author = {Chitambar, E. and Gour, G.},
 doi = {10.1103/PhysRevA.94.052336},
 journal = {Physical Review A},
 number = {5}
}

@article{
 title = {Critical Examination of Incoherent Operations and a Physically Consistent Resource Theory of Quantum Coherence},
 type = {article},
 year = {2016},
 volume = {117},
 id = {8613c0c1-11a3-3e12-8d45-a4a2242ed25f},
 created = {2020-08-20T19:55:39.805Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.805Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2016 American Physical Society. Considerable work has recently been directed toward developing resource theories of quantum coherence. In this Letter, we establish a criterion of physical consistency for any resource theory. This criterion requires that all free operations in a given resource theory be implementable by a unitary evolution and projective measurement that are both free operations in an extended resource theory. We show that all currently proposed basis-dependent theories of coherence fail to satisfy this criterion. We further characterize the physically consistent resource theory of coherence and find its operational power to be quite limited. After relaxing the condition of physical consistency, we introduce the class of dephasing-covariant incoherent operations as a natural generalization of the physically consistent operations. Necessary and sufficient conditions are derived for the convertibility of qubit states using dephasing-covariant operations, and we show that these conditions also hold for other well-known classes of incoherent operations.},
 bibtype = {article},
 author = {Chitambar, E. and Gour, G.},
 doi = {10.1103/PhysRevLett.117.030401},
 journal = {Physical Review Letters},
 number = {3}
}

@article{
 title = {Relating the Resource Theories of Entanglement and Quantum Coherence},
 type = {article},
 year = {2016},
 volume = {117},
 id = {baf627f0-b9bb-392b-992f-c2d139e6b7e6},
 created = {2020-08-20T19:55:39.824Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.824Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2016 American Physical Society. Quantum coherence and quantum entanglement represent two fundamental features of nonclassical systems that can each be characterized within an operational resource theory. In this Letter, we unify the resource theories of entanglement and coherence by studying their combined behavior in the operational setting of local incoherent operations and classical communication (LIOCC). Specifically, we analyze the coherence and entanglement trade-offs in the tasks of state formation and resource distillation. For pure states we identify the minimum coherence-entanglement resources needed to generate a given state, and we introduce a new LIOCC monotone that completely characterizes a state's optimal rate of bipartite coherence distillation. This result allows us to precisely quantify the difference in operational powers between global incoherent operations, LIOCC, and local incoherent operations without classical communication. Finally, a bipartite mixed state is shown to have distillable entanglement if and only if entanglement can be distilled by LIOCC, and we strengthen the well-known Horodecki criterion for distillability.},
 bibtype = {article},
 author = {Chitambar, E. and Hsieh, M.-H.},
 doi = {10.1103/PhysRevLett.117.020402},
 journal = {Physical Review Letters},
 number = {2}
}

@article{
 title = {Asymptotic state discrimination and a strict hierarchy in distinguishability norms},
 type = {article},
 year = {2014},
 volume = {55},
 id = {56338a86-377c-31b5-be61-0acb6f727ef9},
 created = {2020-08-20T19:55:39.872Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.872Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2014 AIP Publishing LLC. In this paper, we consider the problem of discriminating quantum states by local operations and classical communication (LOCC) when an arbitrarily small amount of error is permitted. This paradigm is known as asymptotic state discrimination, and we derive necessary conditions for when two multipartite states of any size can be discriminated perfectly by asymptotic LOCC. We use this new criterion to prove a gap in the LOCC and separable distinguishability norms. We then turn to the operational advantage of using two-way classical communication over one-way communication in LOCC processing. With a simple two-qubit product state ensemble, we demonstrate a strict majorization of the two-way LOCC norm over the one-way norm.},
 bibtype = {article},
 author = {Chitambar, E. and Hsieh, M.-H.},
 doi = {10.1063/1.4902027},
 journal = {Journal of Mathematical Physics},
 number = {11}
}

@article{
 title = {Bell inequalities with communication assistance},
 type = {article},
 year = {2014},
 volume = {89},
 id = {35f997e0-089f-3654-af0f-7ae62492f62a},
 created = {2020-08-20T19:55:39.886Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.886Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {In this paper, we consider the possible correlations between two parties using local machines and shared randomness with an additional amount of classical communication. This is a continuation of the work initiated by Bacon and Toner [Phys. Rev. Lett. 90, 157904 (2003)PRLTAO0031-900710.1103/PhysRevLett. 90.157904] who characterized the correlation polytope for 2×2 measurement settings with binary outcomes plus one bit of communication. Here, we derive a complete set of Bell inequalities for 3×2 measurement settings and a shared bit of communication. When the communication direction is fixed, nine Bell inequalities characterize the correlation polytope, whereas when the communication direction is bidirectional, 143 inequalities describe the correlations. We then prove a tight lower bound on the amount of communication needed to simulate all no-signaling correlations for a given number of measurement settings. © 2014 American Physical Society.},
 bibtype = {article},
 author = {Maxwell, K. and Chitambar, E.},
 doi = {10.1103/PhysRevA.89.042108},
 journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
 number = {4}
}

@article{
 title = {Revisiting the optimal detection of quantum information},
 type = {article},
 year = {2013},
 volume = {88},
 id = {8826f40d-6a51-3119-b381-d63ea00cab3b},
 created = {2020-08-20T19:55:39.910Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.910Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {In 1991, Peres and Wootters wrote a seminal paper on the nonlocal processing of quantum information. We return to their classic problem and solve it in various contexts. Specifically, for discriminating the "double trine" ensemble with minimum error, we prove that global operations are more powerful than local operations with classical communication (LOCC). Even stronger, there exists a finite gap between the optimal LOCC probability and that obtainable by separable operations (SEP). Additionally we prove that a two-way, adaptive LOCC strategy can always beat a one-way protocol. Our results demonstrate "nonlocality without entanglement" in two-qubit pure states. © 2013 American Physical Society.},
 bibtype = {article},
 author = {Chitambar, E. and Hsieh, M.-H.},
 doi = {10.1103/PhysRevA.88.020302},
 journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
 number = {2}
}

@article{
 title = {Nonlocal Entanglement Transformations Achievable by Separable Operations},
 type = {article},
 year = {2009},
 volume = {103},
 id = {0eba58dc-d2c5-3987-8054-189e1f7c81f4},
 created = {2020-08-20T19:55:39.933Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.933Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {The weird phenomenon of "quantum nonlocality without entanglement" means that local quantum operations assisted by classical communication constitute a proper subset of the class of separable quantum operations. Despite considerable recent advances, little is known to what extent the class of separable operations differs from local quantum operations and classical communication. In this Letter we show that separable operations are generally stronger than local quantum operations and classical communication when distilling a mixed state into a pure entangled state and thus confirm the existence of entanglement monotones that can increase under separable operations. Our finding can also be interpreted as confirming the ability of separable operations to enhance the entanglement of mixed states relative to certain measures, a sensible but important fact that has never been rigorously proven before. © 2009 The American Physical Society.},
 bibtype = {article},
 author = {Chitambar, E. and Duan, R.},
 doi = {10.1103/PhysRevLett.103.110502},
 journal = {Physical Review Letters},
 number = {11}
}

@article{
 title = {Complete Resource Theory of Quantum Incompatibility as Quantum Programmability},
 type = {article},
 year = {2020},
 volume = {124},
 id = {940a84ef-16a7-39bc-a6c7-976cccd706f0},
 created = {2020-08-20T19:55:39.959Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:39.959Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2020 American Physical Society. Measurement incompatibility describes two or more quantum measurements whose expected joint outcome on a given system cannot be defined. This purely nonclassical phenomenon provides a necessary ingredient in many quantum information tasks such as violating a Bell inequality or nonlocally steering part of an entangled state. In this Letter, we characterize incompatibility in terms of programmable measurement devices and the general notion of quantum programmability. This refers to the temporal freedom a user has in issuing programs to a quantum device. For devices with a classical control and classical output, measurement incompatibility emerges as the essential quantum resource embodied in their functioning. Based on the processing of programmable measurement devices, we construct a quantum resource theory of incompatibility. A complete set of convertibility conditions for programmable devices is derived based on quantum state discrimination with postmeasurement information.},
 bibtype = {article},
 author = {Buscemi, F. and Chitambar, E. and Zhou, W.},
 doi = {10.1103/PhysRevLett.124.120401},
 journal = {Physical Review Letters},
 number = {12}
}

@article{
 title = {One-shot assisted concentration of coherence},
 type = {article},
 year = {2018},
 keywords = {assisted concentration of coherence,quantum coherence,quantum information},
 volume = {51},
 id = {079b5cfa-bee5-32b7-93fd-b84a875d3e98},
 created = {2020-08-20T19:55:40.010Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.010Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2018 IOP Publishing Ltd. We find one-shot bounds for concentration of maximally coherent states in the so called assisted scenario. In this setting, Bob is restricted to performing incoherent operations on his quantum system, however he is assisted by Alice, who holds a purification of Bob's state and can send classical data to him. We further show that in the asymptotic limit our one-shot bounds recover the previously computed rate of asymptotic assisted concentration.},
 bibtype = {article},
 author = {Vijayan, M.K. and Chitambar, E. and Hsieh, M.-H.},
 doi = {10.1088/1751-8121/aadc21},
 journal = {Journal of Physics A: Mathematical and Theoretical},
 number = {41}
}

@article{
 title = {The Conditional Common Information in Classical and Quantum Secret Key Distillation},
 type = {article},
 year = {2018},
 keywords = {Quantum cryptography,common information,quantum information,secret key distillation},
 volume = {64},
 id = {4afb2101-5389-3b82-96e6-109eb342fb4a},
 created = {2020-08-20T19:55:40.028Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.028Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2018 IEEE. In this paper, we consider two extensions of the Gács-Körner common information to three variables, the conditional common information (cCI) and the coarse-grained conditional common information (ccCI). Both quantities are shown to be useful technical tools in the study of classical and quantum resource transformations. In particular, the ccCI is shown to have an operational interpretation as the optimal rate of secret key extraction from an eavesdropped classical source pXYZ when Alice (X) and Bob (Y) are unable to communicate but share common randomness with the eavesdropper Eve (Z). Moving to the quantum setting, we consider two different ways of generating a tripartite quantum state from classical correlations pXYZ : 1) coherent encodings ∑xyz√pxyz|xyz〉 and 2) incoherent encodings ∑xyzpxyz|xyz〉〈xyz|. We study how well can Alice and Bob extract secret key from these quantum sources using quantum operations compared with the extraction of key from the underlying classical sources pXYZ using classical operations. While the power of quantum mechanics increases Alice and Bob's ability to generate shared randomness, it also equips Eve with a greater arsenal of eavesdropping attacks. Therefore, it is not obvious who gains the greatest advantage for distilling secret key when replacing a classical source with a quantum one. We first demonstrate that the classical key rate of pXYZ is equivalent to the quantum key rate for an incoherent quantum encoding of the distribution. For coherent encodings, we next show that the classical and quantum rates are generally incomparable, and in fact, their difference can be arbitrarily large in either direction. Finally, we introduce a "zoo" of entangled tripartite states all characterized by the conditional common information of their encoded probability distributions. Remarkably, for these states almost all entanglement measures, such as Alice and Bob's entanglement cost, squashed entanglement, and relative entropy of entanglement, can be sharply bounded or even exactly expressed in terms of the conditional common information. In the latter case, we thus present a rare instance in which the various entropic entanglement measures of a quantum state can be explicitly calculated.},
 bibtype = {article},
 author = {Chitambar, E. and Fortescue, B. and Hsieh, M.-H.},
 doi = {10.1109/TIT.2018.2851564},
 journal = {IEEE Transactions on Information Theory},
 number = {11}
}

@article{
 title = {Open system quantum evolution and the assumption of complete positivity (A Tutorial)},
 type = {article},
 year = {2016},
 keywords = {Open quantum systems,dynamical maps,positive maps},
 volume = {14},
 id = {0e3bd8e9-092c-3e48-a9c5-fc92052e53b3},
 created = {2020-08-20T19:55:40.049Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.049Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2016 World Scientific Publishing Company. Quantum systems which interact with an unknown environment cannot be described in terms of a unitary evolution on the system alone. For such evolution one can use a map from one density operator to another and use any other known information to model the system. Such maps are required to be positive (at least on their domain) - they take positive density operators to positive density operators - so as to be physically reasonable. A map Φ which is positive but not completely positive (CP) is one which takes positive operators to positive operators, but when extended by the identity In, i.e. In In⊗ Φ does not give a positive map for some In. The map is CP if and only if the extension is positive for all n. Recently some effort has been put forth to try to understand if, and/or, under what circumstances one might utilize a non-CP map. Here, after a tutorial-type introduction to maps from one density operator to another, some examples which do not fit the standard prescription (SP) for deriving a CP map are given. In cases where the physical system is constrained by some knowledge of the interaction, it is possible that the SP cannot be used directly. Our example is robust to changes in the initial and final conditions.},
 bibtype = {article},
 author = {Byrd, M. and Ceballos, R. and Chitambar, E.},
 doi = {10.1142/S0219749916400232},
 journal = {International Journal of Quantum Information},
 number = {6}
}

@article{
 title = {The private and public correlation cost of three random variables with collaboration},
 type = {article},
 year = {2016},
 keywords = {Wyner common information,local operations and public communication,reverse shannon theorem,secret key cost},
 volume = {62},
 id = {13cefc10-8643-3c40-abc2-efddff4747c4},
 created = {2020-08-20T19:55:40.072Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.072Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2016 IEEE. In this paper, we consider the problem of generating arbitrary three-party correlations from a combination of public and secret correlations. Two parties - called Alice and Bob - share perfectly correlated bits that are secret from a collaborating third party, Charlie. At the same time, all three parties have access to a separate source of correlated bits, and their goal is to convert these two resources into multiple copies of some given tripartite distribution ℙ(XYZ). We obtain a single-letter characterization of the tradeoff between public and private bits that are needed to achieve this task. The rate of private bits is shown to generalize Wyner's classic notion of common information held between a pair of random variables. The problem we consider can be contrasted fruitfully with the task of secrecy formation, in which ℙ(XYZ) is generated using public communication and local randomness but with Charlie functioning as an adversary instead of a collaborator. We describe in detail the differences between the collaborative and adversarial scenarios.},
 bibtype = {article},
 author = {Chitambar, E. and Hsieh, M.-H. and Winter, A.},
 doi = {10.1109/TIT.2016.2530086},
 journal = {IEEE Transactions on Information Theory},
 number = {4}
}

@book{
 title = {Distributions attaining secret key at a rate of the conditional mutual information},
 type = {book},
 year = {2015},
 source = {Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)},
 keywords = {Gàcs-Körner Common Information,Information-theoretic security,Public key agreement},
 volume = {9216},
 id = {3bb5d92c-fa13-3ef1-b853-8acd18d2561a},
 created = {2020-08-20T19:55:40.096Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.096Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© International Association for Cryptologic Research 2015. In this paper we consider the problem of extracting secret key from an eavesdropped source pXY Z at a rate given by the conditional mutual information. We investigate this question under three different scenarios: (i) Alice (X) and Bob (Y) are unable to communicate but share common randomness with the eavesdropper Eve (Z), (ii) Alice and Bob are allowed one-way public communication, and (iii) Alice and Bob are allowed two-way public communication. Distributions having a key rate of the conditional mutual information are precisely those in which a “helping” Eve offers Alice and Bob no greater advantage for obtaining secret key than a fully adversarial one. For each of the above scenarios, strong necessary conditions are derived on the structure of distributions attaining a secret key rate of I(X: Y |Z). In obtaining our results, we completely solve the problem of secret key distillation under scenario (i) and identify H(S|Z) to be the optimal key rate using shared randomness, where S is the Gàcs-Körner Common Information. We thus provide an operational interpretation of the conditional Gàcs- Körner Common Information. Additionally, we introduce simple example distributions in which the rate I(X: Y |Z) is achievable if and only if two-way communication is allowed.},
 bibtype = {book},
 author = {Chitambar, E. and Fortescue, B. and Hsieh, M.-H.},
 doi = {10.1007/978-3-662-48000-7_22}
}

@article{
 title = {Classical Analog to Entanglement Reversibility},
 type = {article},
 year = {2015},
 volume = {115},
 id = {3add2917-c28c-377b-9275-2a1cec39c388},
 created = {2020-08-20T19:55:40.119Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.119Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2015 American Physical Society. In this Letter we study the problem of secrecy reversibility. This asks when two honest parties can distill secret bits from some tripartite distribution pXYZ and transform secret bits back into pXYZ at equal rates using local operation and public communication. This is the classical analog to the well-studied problem of reversibly concentrating and diluting entanglement in a quantum state. We identify the structure of distributions possessing reversible secrecy when one of the honest parties holds a binary distribution, and it is possible that all reversible distributions have this form. These distributions are more general than what is obtained by simply constructing a classical analog to the family of quantum states known to have reversible entanglement. An indispensable tool used in our analysis is a conditional form of the Gács-Körner common information.},
 bibtype = {article},
 author = {Chitambar, E. and Fortescue, B. and Hsieh, M.-H.},
 doi = {10.1103/PhysRevLett.115.090501},
 journal = {Physical Review Letters},
 number = {9}
}

@article{
 title = {When do local operations and classical communication suffice for two-qubit state discrimination?},
 type = {article},
 year = {2014},
 keywords = {LOCC,nonlocality without entanglement,state discrimination,trine ensembles},
 volume = {60},
 id = {211f0fec-77a0-36de-ba4b-7ad78061dabb},
 created = {2020-08-20T19:55:40.163Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.163Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {In this paper, we consider the conditions under which a given ensemble of two-qubit states can be optimally distinguished by local operations and classical communication (LOCC). We begin by completing the perfect distinguishability problem of two-qubit ensembles - both for separable operations and LOCC - by providing necessary and sufficient conditions for the perfect discrimination of one pure and one mixed state. Then, for the well-known task of minimum error discrimination, it is shown that almost all two-qubit ensembles consisting of three pure states cannot be optimally discriminated using LOCC. This is surprising considering that any two pure states can be distinguished optimally by LOCC. Special attention is given to ensembles that lack entanglement, and we prove an easy sufficient condition for when a set of three product states cannot be optimally distinguished by LOCC, thus providing new examples of the phenomenon known as non-locality without entanglement. We next consider an example of N parties who each share the same state but who are ignorant of its identity. The state is drawn from the rotationally invariant trine ensemble, and we establish a tight connection between the N-copy ensemble and Shor's lifted single-copy ensemble. For any finite N, we prove that optimal identification of the states cannot be achieved by LOCC; however, as N → ∞, LOCC can indeed discriminate the states optimally. This is the first result of its kind. Finally, we turn to the task of unambiguous discrimination and derive new lower bounds on the LOCC inconclusive probability for symmetric states. When applied to the double trine ensemble, this leads to a rather different distinguishability character than when the minimum error probability is considered. © 1963-2012 IEEE.},
 bibtype = {article},
 author = {Chitambar, E. and Duan, R. and Hsieh, M.-H.},
 doi = {10.1109/TIT.2013.2295356},
 journal = {IEEE Transactions on Information Theory},
 number = {3}
}

@article{
 title = {Entanglement monotones for W-type states},
 type = {article},
 year = {2012},
 volume = {85},
 id = {9bfe29c1-d69b-3d97-a36d-e67f749c7517},
 created = {2020-08-20T19:55:40.183Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.183Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {In this article, we extend recent results concerning random-pair Einstein-Podolsky-Rosen distillation and the operational gap between separable operations (SEPs) and local operations with classical communication (LOCC). In particular, we consider the problem of obtaining bipartite maximal entanglement from an N-qubit W-class state (i.e., that of the form √x 0|000+√x 1|100++√x n|00) when the target pairs are a priori unspecified. We show that when x 0=0, the optimal probabilities for SEPs can be computed using semidefinite programming. On the other hand, to bound the optimal probabilities achievable by LOCC, we introduce entanglement monotones defined on the N-qubit W class of states. The LOCC monotones we construct can be increased by SEPs, and in terms of transformation success probability, we are able to quantify a gap as large as 37% between the two classes. Additionally, we demonstrate transformations ρ -n→σ -n that are feasible by SEP for any n but impossible by LOCC. © 2012 American Physical Society.},
 bibtype = {article},
 author = {Chitambar, E. and Cui, W. and Lo, H.-K.},
 doi = {10.1103/PhysRevA.85.062316},
 journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
 number = {6}
}

@article{
 title = {Increasing entanglement monotones by separable operations},
 type = {article},
 year = {2012},
 volume = {108},
 id = {92f45f3d-87c7-38b3-ad64-61f91d182693},
 created = {2020-08-20T19:55:40.206Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.206Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Quantum entanglement is fundamentally related to the operational setting of local quantum operations and classical communication (LOCC). A more general class of operations known as separable operations (SEP) is often employed to approximate LOCC, but the exact difference between LOCC and SEP is unknown. In this letter, we compare the two classes in performing particular tripartite to bipartite entanglement conversions and report a gap as large as 12.5% between SEP and LOCC, which is the first known appreciable gap between the classes. Our results rely on constructing a computable entanglement monotone with a clear operational meaning that, unlike all other such monotones previously studied, is not monotonic under SEP. Finally, we prove the curious fact that convergent sequences of LOCC protocols need not be LOCC feasible in the limit. © 2012 American Physical Society.},
 bibtype = {article},
 author = {Chitambar, E. and Cui, W. and Lo, H.-K.},
 doi = {10.1103/PhysRevLett.108.240504},
 journal = {Physical Review Letters},
 number = {24}
}

@article{
 title = {Randomly distilling W-class states into general configurations of two-party entanglement},
 type = {article},
 year = {2011},
 volume = {84},
 id = {1fe832a4-4bc3-3bd3-a230-ba8150945c56},
 created = {2020-08-20T19:55:40.250Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.250Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {In this article we obtain results for the task of converting a single N-qubit W-class state (of the form √x0|00...0+√x 1|10...0++√xN|00...1) into maximum entanglement shared between two random parties. Previous studies in random distillation have not considered how the particular choice of target pairs affects the transformation, and here we develop a strategy for distilling into general configurations of target pairs. We completely solve the problem of determining the optimal distillation probability for all three-qubit configurations and most four-qubit configurations when x0=0. Our proof involves deriving new entanglement monotones defined on the set of four-qubit W-class states. As an additional application of our results, we present new upper bounds for converting a generic W-class state into the standard W state |W N=√1N(|10...0++|00...1). © 2011 American Physical Society.},
 bibtype = {article},
 author = {Cui, W. and Chitambar, E. and Lo, H.K.},
 doi = {10.1103/PhysRevA.84.052301},
 journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
 number = {5}
}

@article{
 title = {Deciding unitary equivalence between matrix polynomials and sets of bipartite quantum states},
 type = {article},
 year = {2011},
 keywords = {H zbinden,Matrix polynomials,Schwartz-zippel lemma communicated by: S braunstei,Unitary transformations},
 volume = {11},
 id = {47f31127-0f1a-3734-9de4-a259ab05f43a},
 created = {2020-08-20T19:55:40.263Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.263Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {In this brief report, we consider the equivalence between two sets of m + 1 bipartite quantum states under local unitary transformations. For pure states, this problem corresponds to the matrix algebra question of whether two degree m matrix polynomials are unitarily equivalent; i.e. UAiV† = Bi for 0 < i < m where U and V are unitary and (Ai, Bi) are arbitrary pairs of rectangular matrices. We present a randomized polynomial-time algorithm that solves this problem with an arbitrarily high success probability and outputs transforming matrices U and V. © Rinton Press.},
 bibtype = {article},
 author = {Chitambar, E. and Miller, C.A. and Shi, Y.},
 journal = {Quantum Information and Computation},
 number = {9-10}
}

@article{
 title = {Two local observables are sufficient to characterize maximally entangled states of N qubits},
 type = {article},
 year = {2011},
 volume = {83},
 id = {e68c1f66-9a74-3301-812a-ac73d93149ba},
 created = {2020-08-20T19:55:40.291Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.291Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Maximally entangled states (MES) represent a valuable resource in quantum information processing. In N-qubit systems the MES are N-GHZ states [i.e., the collection of |GHZ N =1 √2(|00...0 +|11...1 )] and its local unitary (LU) equivalences. While it is well known that such states are uniquely stabilized by N commuting observables, in this article we consider the minimum number of noncommuting observables needed to characterize an N-qubit MES as the unique common eigenstate. Here, we prove, rather surprisingly, that in this general case any N-GHZ state can be uniquely stabilized by only two observables. Thus, for the task of MES certification, only two correlated measurements are required with each party observing the spin of his or her system along one of two directions. © 2011 American Physical Society.},
 bibtype = {article},
 author = {Yan, F. and Gao, T. and Chitambar, E.},
 doi = {10.1103/PhysRevA.83.022319},
 journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
 number = {2}
}

@article{
 title = {Optimal entanglement transformations among N-qubit W-class states},
 type = {article},
 year = {2010},
 volume = {82},
 id = {6229a88c-87ca-3b0b-b3d4-f6fa916311ca},
 created = {2020-08-20T19:55:40.303Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.303Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {We investigate the physically allowed probabilities for transforming one N-partite W-class state to another by means of local operations assisted with classical communication. Recently, S. Kintaş and S. Turgut [J. Math. Phys.JMAPAQ0022-248810.1063/1.3481573 51, 092202 (2010)] obtained an upper bound for the maximum probability of transforming two such states. Here, we provide a simple sufficient and necessary condition for when this upper bound can be satisfied and, thus, when optimality of state transformation can be achieved. Our discussion involves obtaining lower bounds for the transformation of arbitrary W-class states and showing precisely when this bound saturates the bound of Kintaş and Turgut. Finally, we consider the question of transforming symmetric W-class states and find that, in general, the optimal one-shot procedure for converting two symmetric states requires a nonsymmetric filter by all the parties. © 2010 The American Physical Society.},
 bibtype = {article},
 author = {Cui, W. and Chitambar, E. and Lo, H.-K.},
 doi = {10.1103/PhysRevA.82.062314},
 journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
 number = {6}
}

@article{
 title = {Matrix pencils and entanglement classification},
 type = {article},
 year = {2010},
 volume = {51},
 id = {83925ba3-bf80-30de-af87-c90c4eb550d6},
 created = {2020-08-20T19:55:40.333Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.333Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Quantum entanglement plays a central role in quantum information processing. A main objective of the theory is to classify different types of entanglement according to their interconvertibility through manipulations that do not require additional entanglement to perform. While bipartite entanglement is well understood in this framework, the classification of entanglements among three or more subsystems is inherently much more difficult. In this paper, we study pure state entanglement in systems of dimension 2⊗m⊗n. Two states are considered equivalent if they can be reversibly converted from one to the other with a nonzero probability using only local quantum resources and classical communication (SLOCC). We introduce a connection between entanglement manipulations in these systems and the well-studied theory of matrix pencils. All previous attempts to study general SLOCC equivalence in such systems have relied on somewhat contrived techniques which fail to reveal the elegant structure of the problem that can be seen from the matrix pencil approach. Based on this method, we report the first polynomial-time algorithm for deciding when two 2⊗m⊗n states are SLOCC equivalent. We then proceed to present a canonical form for all 2⊗m⊗n states based on the matrix pencil construction such that two states are equivalent if and only if they have the same canonical form. Besides recovering the previously known 26 distinct SLOCC equivalence classes in 2⊗3⊗n systems, we also determine the hierarchy between these classes. © 2010 American Institute of Physics.},
 bibtype = {article},
 author = {Chitambar, E. and Miller, C.A. and Shi, Y.},
 doi = {10.1063/1.3459069},
 journal = {Journal of Mathematical Physics},
 number = {7}
}

@article{
 title = {Multipartite-to-bipartite entanglement transformations and polynomial identity testing},
 type = {article},
 year = {2010},
 volume = {81},
 id = {3e32439c-f2a5-3109-ae5b-7e9faa269ef8},
 created = {2020-08-20T19:55:40.339Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.339Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {We consider the problem of deciding if some multiparty entangled pure state can be converted, with a nonzero success probability, into a given bipartite pure state shared between two specified parties through local quantum operations and classical communication. We show that this question is equivalent to the well-known computational problem of deciding if a multivariate polynomial is identically zero. Efficient randomized algorithms developed to study the latter can thus be applied to our question. As a result, a given transformation is possible if and only if it is generically attainable by a simple randomized protocol. © 2010 The American Physical Society.},
 bibtype = {article},
 author = {Chitambar, E. and Duan, R. and Shi, Y.},
 doi = {10.1103/PhysRevA.81.052310},
 journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
 number = {5}
}

@article{
 title = {Tripartite entanglement transformations and tensor rank},
 type = {article},
 year = {2008},
 volume = {101},
 id = {ec321753-91c8-3e30-9965-f98723cabc89},
 created = {2020-08-20T19:55:40.378Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.378Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {A basic question regarding quantum entangled states is whether one can be probabilistically converted to another through local operations and classical communication exclusively. While the answer for bipartite systems is known, we show that for tripartite systems, this question encodes some of the most challenging open problems in mathematics and computer science. In particular, we show that there is no easy general criterion to determine the feasibility, and in fact, the problem is NP hard. In addition, we find obtaining the most efficient algorithm for matrix multiplication to be precisely equivalent to determining the maximum rate to convert the Greenberger-Horne-Zeilinger state to a triangular distribution of three EPR states. Our results are based on connections between multipartite entanglement and tensor rank (also called Schmidt rank), a key concept in algebraic complexity theory. © 2008 The American Physical Society.},
 bibtype = {article},
 author = {Chitambar, E. and Duan, R. and Shi, Y.},
 doi = {10.1103/PhysRevLett.101.140502},
 journal = {Physical Review Letters},
 number = {14}
}

@article{
 title = {Channel activation of CHSH nonlocality},
 type = {article},
 year = {2020},
 keywords = {Chsh breaking channel,Nonlocality breaking channel,Superactivation},
 volume = {22},
 id = {b44e6ebc-ae9f-39e8-b625-f296dc8897e3},
 created = {2020-08-20T19:55:40.385Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.385Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2020 The Author(s). Published by IOP Publishing Ltd on behalf of the Institute of Physics and Deutsche Physikalische Gesellschaft. Quantum channels that break CHSH nonlocality on all input states are known as CHSH-breaking channels. In quantum networks, such channels are useless for distributing correlations that can violate the CHSH Inequality. Motivated by previous work on activation of nonlocality in quantum states, here we demonstrate an analogous activation of CHSH-breaking channels. That is, we show that certain pairs of CHSH-breaking channels are no longer CHSH-breaking when used in combination. We find that this type of activation can emerge in both uni-directional and bi-directional communication scenarios.},
 bibtype = {article},
 author = {Zhang, Y. and Bravo, R.A. and Lorenz, V.O. and Chitambar, E.},
 doi = {10.1088/1367-2630/ab7bef},
 journal = {New Journal of Physics},
 number = {4}
}

@article{
 title = {Entanglement manipulation beyond local operations and classical communication},
 type = {article},
 year = {2020},
 volume = {61},
 id = {bd9a9d58-2c6a-308c-98f1-9cc68b2397f8},
 created = {2020-08-20T19:55:40.423Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.423Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2020 Author(s). When a quantum system is distributed to spatially separated parties, it is natural to consider how the system evolves when the parties perform local quantum operations with classical communication (LOCC). However, the structure of LOCC channels is exceedingly complex, leaving many important physical problems unsolved. In this paper, we consider generalized resource theories of entanglement based on different relaxations to the class of LOCC. The behavior of various entanglement measures is studied under non-entangling channels, as well as the newly introduced classes of dually non-entangling and positive partial transpose (PPT)-preserving channels. In an effort to better understand the nature of LOCC bound entanglement, we study the problem of entanglement distillation in these generalized resource theories. We first show that unlike LOCC, general non-entangling maps can be superactivated, in the sense that two copies of the same non-entangling map can, nevertheless, be entangling. On the single-copy level, we demonstrate that every NPT entangled state can be converted into an LOCC-distillable state using channels that are both dually non-entangling and having a PPT Choi representation and that every state can be converted into an LOCC-distillable state using operations belonging to any family of polytopes that approximate LOCC. We then turn to the stochastic convertibility of multipartite pure states and show that any two states can be interconverted by any polytope approximation to the set of separable channels. Finally, as an analog to k-positive maps, we introduce and analyze the set of k-non-entangling channels.},
 bibtype = {article},
 author = {Chitambar, E. and De Vicente, J.I. and Girard, M.W. and Gour, G.},
 doi = {10.1063/1.5124109},
 journal = {Journal of Mathematical Physics},
 number = {4}
}

@article{
 title = {Restrictions on initial system-environment correlations based on the dynamics of an open quantum system},
 type = {article},
 year = {2015},
 volume = {92},
 id = {b3913c87-5a45-3b64-98f2-ea310ec10e78},
 created = {2020-08-20T19:55:40.428Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.428Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2015 American Physical Society. The dynamics of an open quantum system is often modeled by introducing a bath initially in a product state with the system, letting the system and bath evolve unitarily together, and then tracing over the bath. However, often this model may not accurately reflect a particular experimental situation. Here, we provide some restrictions on one's ability to model an open quantum system using an initial product state when some information about the system-bath interaction is known. For instance, when certain symmetries exist in the system-bath interaction, we compute limitations on how much the system's purity can be increased if the bath is initially uncorrelated white noise. Furthermore, when the system and bath are qubits, we find that effectively only swap and product unitaries always generate system dynamics capable of being modeled using an initial product state. Finally, we show how any initial correlations between the system and environment are detectable, in principle, by observing the system transformation alone during certain joint evolutions. Our results have application in experimental quantum control and quantum computing where the system and environment are often assumed to be initially uncorrelated.},
 bibtype = {article},
 author = {Chitambar, E. and Abu-Nada, A. and Ceballos, R. and Byrd, M.},
 doi = {10.1103/PhysRevA.92.052110},
 journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
 number = {5}
}

@article{
 title = {Detecting multipartite classical states and their resemblances},
 type = {article},
 year = {2011},
 volume = {83},
 id = {ec0c19ae-d9ee-3052-97c2-978ccabfbecf},
 created = {2020-08-20T19:55:40.466Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.466Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {We study various types of multipartite states lying near the quantum-classical boundary. The so-called classical states are precisely those in which each party can perfectly identify a locally held state without disturbing the global state, a task known as nondisruptive local state identification (NDLID). We show NDLID to be closely related local broadcasting, and we introduce a class of states called generalized classical states which allow for both NDLID and multipartite broadcasting when the most general quantum measurements are permitted. Simple analytical methods and a physical criterion are given for detecting whether a multipartite state is classical or generalized classical. For deciding the latter, a semidefinite programming algorithm is presented which may find use in other fields such as signal processing. © 2011 American Physical Society.},
 bibtype = {article},
 author = {Chen, L. and Chitambar, E. and Modi, K. and Vacanti, G.},
 doi = {10.1103/PhysRevA.83.020101},
 journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
 number = {2}
}

@article{
 title = {Tensor rank of the tripartite state |W n},
 type = {article},
 year = {2010},
 volume = {81},
 id = {d58fee13-3db1-3a9e-9623-377e7b12050c},
 created = {2020-08-20T19:55:40.473Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.473Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Tensor rank refers to the number of product states needed to express a given multipartite quantum state. Its nonadditivity as an entanglement measure has recently been observed. In this Brief Report, we estimate the tensor rank of multiple copies of the tripartite state |W=13(|100+|010+|001). Both an upper bound and a lower bound of this rank are derived. In particular, it is proven that the rank of |W 2 is 7, thus resolving a previously open problem. Some implications of this result are discussed in terms of transformation rates between |Wn and multiple copies of the state |GHZ=12(|000+|111). © 2010 The American Physical Society.},
 bibtype = {article},
 author = {Yu, N. and Chitambar, E. and Guo, C. and Duan, R.},
 doi = {10.1103/PhysRevA.81.014301},
 journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
 number = {1}
}

@article{
 title = {One-Shot Coherence Distillation: Towards Completing the Picture},
 type = {article},
 year = {2019},
 keywords = {Quantum coherence,coherence distillation,one-shot,quantum resource theory},
 volume = {65},
 id = {05d81eb1-a738-339e-9b07-4acb9ecdc99b},
 created = {2020-08-20T19:55:40.513Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.513Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 1963-2012 IEEE. The resource framework of quantum coherence was introduced by Baumgratz, Cramer, and Plenio [Phys. Rev. Lett. 113, 140401 (2014)] and further developed by Winter and Yang [Phys. Rev. Lett. 116, 120404 (2016)]. We consider the one-shot problem of distilling pure coherence from a single instance of a given resource state. Specifically, we determine the distillable coherence with a given fidelity under incoherent operations (IO) through a generalization of the Winter-Yang protocol. This is compared to the distillable coherence under maximal incoherent operations (MIO) and dephasing-covariant incoherent operations (DIO), which can be cast as a semidefinite programme, that has been presented previously by Regula et al. [Phys. Rev. Lett. 121, 010401 (2018)]. Our results are given in terms of a smoothed min-relative entropy distance from the incoherent set of states, and a variant of the hypothesis-testing relative entropy distance, respectively. The one-shot distillable coherence is also related to one-shot randomness extraction. Moreover, from the one-shot formulas under IO, MIO, and DIO, we can recover the optimal distillable rate in the many-copy asymptotics, yielding the relative entropy of coherence. These results can be compared with previous work by some of the present authors [Zhao et al., Phys. Rev. Lett. 120, 070403 (2018)] on one-shot coherence formation under IO, MIO, DIO and also SIO. This shows that the amount of distillable coherence is essentially the same for IO, DIO, and MIO, despite the fact that the three classes of operations are very different. We also relate the distillable coherence under strictly incoherent operations (SIO) to a constrained hypothesis testing problem and explicitly show the existence of bound coherence under SIO in the asymptotic regime.},
 bibtype = {article},
 author = {Zhao, Q. and Liu, Y. and Yuan, X. and Chitambar, E. and Winter, A.},
 doi = {10.1109/TIT.2019.2911102},
 journal = {IEEE Transactions on Information Theory},
 number = {10}
}

@article{
 title = {One-Shot Coherence Dilution},
 type = {article},
 year = {2018},
 volume = {120},
 id = {098aadac-771d-306d-99af-fd57ec84d625},
 created = {2020-08-20T19:55:40.516Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.516Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2018 American Physical Society. Manipulation and quantification of quantum resources are fundamental problems in quantum physics. In the asymptotic limit, coherence distillation and dilution have been proposed by manipulating infinite identical copies of states. In the nonasymptotic setting, finite data-size effects emerge, and the practically relevant problem of coherence manipulation using finite resources has been left open. This Letter establishes the one-shot theory of coherence dilution, which involves converting maximally coherent states into an arbitrary quantum state using maximally incoherent operations, dephasing-covariant incoherent operations, incoherent operations, or strictly incoherent operations. We introduce several coherence monotones with concrete operational interpretations that estimate the one-shot coherence cost - the minimum amount of maximally coherent states needed for faithful coherence dilution. Furthermore, we derive the asymptotic coherence dilution results with maximally incoherent operations, incoherent operations, and strictly incoherent operations as special cases. Our result can be applied in the analyses of quantum information processing tasks that exploit coherence as resources, such as quantum key distribution and random number generation.},
 bibtype = {article},
 author = {Zhao, Q. and Liu, Y. and Yuan, X. and Chitambar, E. and Ma, X.},
 doi = {10.1103/PhysRevLett.120.070403},
 journal = {Physical Review Letters},
 number = {7}
}

@article{
 title = {Everything You Always Wanted to Know About LOCC (ButWere Afraid to Ask)},
 type = {article},
 year = {2014},
 volume = {328},
 id = {893a4a8b-b751-3122-ba65-52cbe6748e39},
 created = {2020-08-20T19:55:40.559Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.559Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2014, Springer-Verlag Berlin Heidelberg. In this paper we study the subset of generalized quantum measurements on finite dimensional systems known as local operations and classical communication (LOCC). While LOCC emerges as the natural class of operations in many important quantum information tasks, its mathematical structure is complex and difficult to characterize. Here we provide a precise description of LOCC and related operational classes in terms of quantum instruments. Our formalism captures both finite round protocols as well as those that utilize an unbounded number of communication rounds.While the set of LOCC is not topologically closed, we show that finite round LOCC constitutes a compact subset of quantum operations. Additionally we show the existence of an open ball around the completely depolarizing map that consists entirely of LOCC implementable maps. Finally, we demonstrate a two-qubit map whose action can be approached arbitrarily close using LOCC, but nevertheless cannot be implemented perfectly.},
 bibtype = {article},
 author = {Chitambar, E. and Leung, D. and Mančinska, L. and Ozols, M. and Winter, A.},
 doi = {10.1007/s00220-014-1953-9},
 journal = {Communications in Mathematical Physics},
 number = {1}
}

@article{
 title = {Tensor rank and stochastic entanglement catalysis for multipartite pure states},
 type = {article},
 year = {2010},
 volume = {105},
 id = {48b80676-6ee1-3853-8a94-4018298f4624},
 created = {2020-08-20T19:55:40.562Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.562Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {The tensor rank (also known as generalized Schmidt rank) of multipartite pure states plays an important role in the study of entanglement classifications and transformations. We employ powerful tools from the theory of homogeneous polynomials to investigate the tensor rank of symmetric states such as the tripartite state |W3=1√3(|100+|010+|001) and its N-partite generalization |WN. Previous tensor rank estimates are dramatically improved and we show that (i) three copies of |W3 have a rank of either 15 or 16, (ii) two copies of |WN have a rank of 3N-2, and (iii) n copies of |WN have a rank of O(N). A remarkable consequence of these results is that certain multipartite transformations, impossible even probabilistically, can become possible when performed in multiple-copy bunches or when assisted by some catalyzing state. This effect is impossible for bipartite pure states. © 2010 The American Physical Society.},
 bibtype = {article},
 author = {Chen, L. and Chitambar, E. and Duan, R. and Ji, Z. and Winter, A.},
 doi = {10.1103/PhysRevLett.105.200501},
 journal = {Physical Review Letters},
 number = {20}
}

@article{
 title = {Loss-tolerant quantum secure positioning with weak laser sources},
 type = {article},
 year = {2016},
 volume = {94},
 id = {3ec9537c-2c12-34c4-a600-3131eea4ffb4},
 created = {2020-08-20T19:55:40.601Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.601Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2016 American Physical Society. Quantum position verification (QPV) is the art of verifying the geographical location of an untrusted party. Recently, it has been shown that the widely studied Bennett & Brassard 1984 (BB84) QPV protocol is insecure after the 3 dB loss point assuming local operations and classical communication (LOCC) adversaries. Here, we propose a time-reversed entanglement swapping QPV protocol (based on measurement-device-independent quantum cryptography) that is highly robust against quantum channel loss. First, assuming ideal qubit sources, we show that the protocol is secure against LOCC adversaries for any quantum channel loss, thereby overcoming the 3 dB loss limit. Then, we analyze the security of the protocol in a more practical setting involving weak laser sources and linear optics. In this setting, we find that the security only degrades by an additive constant and the protocol is able to verify positions up to 47 dB channel loss.},
 bibtype = {article},
 author = {Lim, C.C.W. and Xu, F. and Siopsis, G. and Chitambar, E. and Evans, P.G. and Qi, B.},
 doi = {10.1103/PhysRevA.94.032315},
 journal = {Physical Review A},
 number = {3}
}

@article{
 title = {Entanglement and Coherence in Quantum State Merging},
 type = {article},
 year = {2016},
 volume = {116},
 id = {a8d15d70-122f-3796-9f10-5b650bc7e4b8},
 created = {2020-08-20T19:55:40.608Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.608Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2016 American Physical Society. Understanding the resource consumption in distributed scenarios is one of the main goals of quantum information theory. A prominent example for such a scenario is the task of quantum state merging, where two parties aim to merge their tripartite quantum state parts. In standard quantum state merging, entanglement is considered to be an expensive resource, while local quantum operations can be performed at no additional cost. However, recent developments show that some local operations could be more expensive than others: it is reasonable to distinguish between local incoherent operations and local operations which can create coherence. This idea leads us to the task of incoherent quantum state merging, where one of the parties has free access to local incoherent operations only. In this case the resources of the process are quantified by pairs of entanglement and coherence. Here, we develop tools for studying this process and apply them to several relevant scenarios. While quantum state merging can lead to a gain of entanglement, our results imply that no merging procedure can gain entanglement and coherence at the same time. We also provide a general lower bound on the entanglement-coherence sum and show that the bound is tight for all pure states. Our results also lead to an incoherent version of Schumacher compression: in this case the compression rate is equal to the von Neumann entropy of the diagonal elements of the corresponding quantum state.},
 bibtype = {article},
 author = {Streltsov, A. and Chitambar, E. and Rana, S. and Bera, M.N. and Winter, A. and Lewenstein, M.},
 doi = {10.1103/PhysRevLett.116.240405},
 journal = {Physical Review Letters},
 number = {24}
}

@article{
 title = {Assisted Distillation of Quantum Coherence},
 type = {article},
 year = {2016},
 volume = {116},
 id = {b5a2dda9-8007-3be0-8d57-ae0a1d4b785f},
 created = {2020-08-20T19:55:40.655Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.655Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2016 American Physical Society. We introduce and study the task of assisted coherence distillation. This task arises naturally in bipartite systems where both parties work together to generate the maximal possible coherence on one of the subsystems. Only incoherent operations are allowed on the target system, while general local quantum operations are permitted on the other; this is an operational paradigm that we call local quantum-incoherent operations and classical communication. We show that the asymptotic rate of assisted coherence distillation for pure states is equal to the coherence of assistance, an analog of the entanglement of assistance, whose properties we characterize. Our findings imply a novel interpretation of the von Neumann entropy: it quantifies the maximum amount of extra quantum coherence a system can gain when receiving assistance from a collaborative party. Our results are generalized to coherence localization in a multipartite setting and possible applications are discussed.},
 bibtype = {article},
 author = {Chitambar, E. and Streltsov, A. and Rana, S. and Bera, M.N. and Adesso, G. and Lewenstein, M.},
 doi = {10.1103/PhysRevLett.116.070402},
 journal = {Physical Review Letters},
 number = {7}
}

@inproceedings{
 title = {Free-space reconfigurable quantum key distribution network},
 type = {inproceedings},
 year = {2016},
 id = {958d0a84-e026-34d2-8685-758e8b7313e9},
 created = {2020-08-20T19:55:40.664Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-08-20T19:55:40.664Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2015 IEEE. We propose a free-space reconfigurable quantum key distribution (QKD) network to secure communication among mobile users. Depends on the trustworthiness of the network relay, the users can implement either the highly secure measurement-device-independent QKD, or the highly efficient decoy state BB84 QKD. Based on the same quantum infrastructure, we also propose a loss tolerant quantum position verification scheme, which could allow the QKD users to initiate the QKD process without relying on pre-shared key.},
 bibtype = {inproceedings},
 author = {Qi, B. and Lo, H.-K. and Lim, C.C.W. and Siopsis, G. and Chitambar, E.A. and Pooser, R. and Evans, P.G. and Grice, W.},
 doi = {10.1109/ICSOS.2015.7425063},
 booktitle = {2015 IEEE International Conference on Space Optical Systems and Applications, ICSOS 2015}
}

@article{
 title = {Entanglement-breaking superchannels},
 type = {article},
 year = {2020},
 volume = {4},
 id = {71f44b56-76d4-3560-bf91-8fc303374b77},
 created = {2020-10-12T23:59:00.000Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-10-15T07:26:13.634Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {© 2020 Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften. All rights reserved. In this paper we initiate the study of entanglement-breaking (EB) superchannels. These are processes that always yield separable maps when acting on one side of a bipartite completely positive (CP) map. EB superchannels are a generalization of the well-known EB channels. We give several equivalent characterizations of EB supermaps and superchannels. Unlike its channel counterpart, we find that not every EB superchannel can be implemented as a measure-and-prepare superchannel. We also demonstrate that many EB superchannels can be superactivated, in the sense that they can output non-separable channels when wired in series. We then introduce the notions of CPTP- and CP-complete images of a superchannel, which capture deterministic and probabilistic channel convertibility, respectively. This allows us to characterize the power of EB superchannels for generating CP maps in different scenarios, and it reveals some fundamental differences between channels and superchannels. Finally, we relax the definition of separable channels to include (p, q)-non-entangling channels, which are bipartite channels that cannot generate entanglement using p- and q-dimensional ancillary systems. By introducing and investigating k-EB maps, we construct examples of (p, q)-EB superchannels that are not fully entanglement breaking. Partial results on the characterization of (p, q)-EB superchannels are also provided.},
 bibtype = {article},
 author = {Chen, S. and Chitambar, E.},
 doi = {10.22331/q-2020-07-16-299},
 journal = {Quantum}
}

@misc{
 title = {One-shot coherence dilution},
 type = {misc},
 year = {2017},
 source = {arXiv},
 id = {6fc95380-ce40-3e52-8c7e-d900dcbf9d05},
 created = {2020-10-27T23:59:00.000Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-10-30T08:41:11.297Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Copyright © 2017, arXiv, All rights reserved. Manipulation and quantification of quantum resources are fundamental problems in quantum physics. In the asymptotic limit, coherence distillation and dilution have been proposed by manipulating infinite identical copies of states. In the nonasymptotic setting, finite data-size effects emerge, and the practically relevant problem of coherence manipulation using finite resources has been left open. This Letter establishes the one-shot theory of coherence dilution, which involves converting maximally coherent states into an arbitrary quantum state using maximally incoherent operations, dephasing-covariant incoherent operations, incoherent operations, or strictly incoherent operations. We introduce several coherence monotones with concrete operational interpretations that estimate the one-shot coherence cost-the minimum amount of maximally coherent states needed for faithful coherence dilution. Furthermore, we derive the asymptotic coherence dilution results with maximally incoherent operations, incoherent operations, and strictly incoherent operations as special cases. Our result can be applied in the analyses of quantum information processing tasks that exploit coherence as resources, such as quantum key distribution and random number generation.},
 bibtype = {misc},
 author = {Zhao, Q. and Liu, Y. and Yuan, X. and Chitambar, E. and Ma, X.}
}

@misc{
 title = {Entanglement manipulation and distillability beyond LOCC},
 type = {misc},
 year = {2017},
 source = {arXiv},
 id = {a3a4a68b-b654-38c2-9bc7-c197ffe03a00},
 created = {2020-10-27T23:59:00.000Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-10-31T01:16:47.915Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Copyright © 2017, arXiv, All rights reserved. When a quantum system is distributed to spatially separated parties, it is natural to consider how the system evolves when the parties perform local quantum operations with classical communication (LOCC). However, the structure of LOCC channels is exceedingly complex leaving many important physical problems unsolved. In this paper we consider generalized resource theories of entanglement based on different relaxations to the class of LOCC. The behavior of various entanglement measures is studied under non-entangling channels, as well as the newly introduced classes of dually non-entangling and PPT-preserving channels. In an effort to better understand the nature of LOCC bound entanglement, we study the problem of entanglement distillation in these generalized resource theories. We first show that unlike LOCC, general non-entangling maps can be superactivated, in the sense that two copies of the same non-entangling map can nevertheless be entangling. On the single-copy level, we demonstrate that every NPT entangled state can be converted into an LOCC-distillable state using channels that are both dually non-entangling and having a PPT Choi representation and that every state can be converted into an LOCC-distillable state using operations belonging to any family of polytopes that approximate LOCC. We then turn to the stochastic convertibility of multipartite pure states and show that any two states can be interconverted by any polytope approximation to the set of separable channels. Finally, as an analog to k-positive maps, we introduce and analyze the set of k-non-entangling channels.},
 bibtype = {misc},
 author = {Chitambar, E. and De Vicente, J.I. and Girard, M.W. and Gour, G.}
}

@misc{
 title = {One-shot distillation in a general resource theory},
 type = {misc},
 year = {2019},
 source = {arXiv},
 id = {4489a828-41da-3770-a4a8-5350ff4f0dce},
 created = {2020-11-03T23:59:00.000Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-11-04T16:59:45.444Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Copyright © 2019, arXiv, All rights reserved. We present a general framework of a quantum resource theory based on the assumption of a) convexity and b) that the overlap of free states with maximally resourceful state is bounded. Using this structure, we derive bounds on the one-shot distillation rate for such a resource theory, thereby reproducing known bounds in coherence and entanglement. We use the free robustness and introduce a function Gmin(ρ) related to overlap between ρ and the set of free states to express our bounds. To deal with resource theories where the free robustness in not finite we introduce the notion of imperfect free operations which we call ϵ-resource generating operations and generalize the free robustness to ϵ-free robustness. We construct an ϵ-resource generating map that achieves pure state transformations in the theory and derive the conditions for such a transformation to exist in terms of the ϵ-free robustness.},
 bibtype = {misc},
 author = {Vijayan, M.K. and Chitambar, E. and Hsieh, M.-H.}
}

@misc{
 title = {Dephasing-Covariant Operations Enable Asymptotic Reversibility of Quantum Resources},
 type = {misc},
 year = {2017},
 source = {arXiv},
 id = {8ac819e4-af60-31cb-b05e-a9d21cb78dce},
 created = {2020-11-03T23:59:00.000Z},
 file_attached = {false},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2020-11-05T01:35:55.742Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Copyright © 2017, arXiv, All rights reserved. We study the power of dephasing-covariant operations in the resource theories of coherence and entanglement. These are quantum operations whose actions commute with a projective measurement. In the resource theory of coherence, we find that any two states are asymptotically interconvertible under dephasing-covariant operations. This provides a rare example of a resource theory in which asymptotic reversibility can be attained without needing the maximal set of resource non-generating operations. When extended to the resource theory of entanglement, the resultant operations share similarities with LOCC, such as prohibiting the increase of all Rényi α-entropies of entanglement under pure state transformations. However, we show these operations are still strong enough to enable asymptotic reversibility between any two maximally correlated mixed states, even in the multipartite setting.},
 bibtype = {misc},
 author = {Chitambar, E.}
}

@article{
 title = {On the Duality of Teleportation and Dense Coding},
 type = {article},
 year = {2024},
 pages = {3529-3537},
 volume = {70},
 websites = {https://ieeexplore.ieee.org/document/10315956/},
 month = {5},
 publisher = {Institute of Electrical and Electronics Engineers Inc.},
 id = {0c5f12d2-17dc-3ba3-a6da-2b7c3897488e},
 created = {2025-04-11T19:50:02.491Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-13T16:53:53.779Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Quantum teleportation is a quantum communication primitive that allows a long-distance quantum channel to be built using pre-shared entanglement and one-way classical communication. However, the quality of the established channel crucially depends on the quality of the pre-shared entanglement. In this work, we revisit the problem of using noisy entanglement for the task of teleportation. We first show how this problem can be rephrased as a state discrimination problem. In this picture, a quantitative duality between teleportation and dense coding emerges in which every Alice-to-Bob teleportation protocol can be repurposed as a Bob-to-Alice dense coding protocol, and the quality of each protocol can be measured by the success probability in the same state discrimination problem. One of our main results provides a complete characterization of the states that offer no advantage in one-way teleportation protocols over classical states, thereby offering a new and intriguing perspective on the long-standing open problem of identifying such states. This also yields a new proof of the known fact that bound entangled states cannot exceed the classical teleportation threshold. Moreover, our established duality between teleportation and dense coding can be used to show that the exact same states are unable to provide a non-classical advantage for dense coding as well. We also discuss the duality from a communication capacity point of view, deriving upper and lower bounds on the accessible information of a dense coding protocol in terms of the fidelity of its associated teleportation protocol. A corollary of this discussion is a simple proof of the previously established fact that bound entangled states do not provide any advantage in dense coding.},
 bibtype = {article},
 author = {Chitambar, Eric and Leditzky, Felix},
 doi = {10.1109/TIT.2023.3331821},
 journal = {IEEE Transactions on Information Theory},
 number = {5}
}

@inproceedings{
 title = {The Communication Value of a Quantum Channel},
 type = {inproceedings},
 year = {2023},
 keywords = {Quantum information science,quantum channels,quantum entanglement},
 pages = {1660-1679},
 volume = {69},
 issue = {3},
 month = {3},
 publisher = {Institute of Electrical and Electronics Engineers Inc.},
 day = {1},
 id = {dae6743e-b456-39b8-99d3-ce430ef1797a},
 created = {2025-04-11T19:50:02.576Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-11T19:50:57.786Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {There are various ways to quantify the communication capabilities of a quantum channel. In this work we introduce the communication value (cv) of quantum channel, which describes the optimal probability of guessing the channel input from its output. By connecting to prior work on zero-error channel simulation, we show that the cv and its entanglement-assisted variant also offer dual interpretations as the classical communication cost for perfectly simulating different aspects of a channel using non-signaling resources. Our study involves characterizing the communication value as a generalized conditional min-entropy over the cone of separable operators. Using this characterization, we evaluate the cv for all qubit channels and higher-dimensional channels with certain symmetries. We find that the any entanglement-breaking channel has multiplicative cv when used in parallel with any other channel; the same is shown to hold for Pauli channels and partially depolarizing channels. In contrast, the cv is found to be non-multiplicative for a subset of the well-known Werner-Holevo channels. A final component of this work investigates relaxations of the channel cv to other cones such as the set of operators having a positive partial transpose (PPT).},
 bibtype = {inproceedings},
 author = {Chitambar, Eric and George, Ian and Doolittle, Brian and Junge, Marius},
 doi = {10.1109/TIT.2022.3218540},
 booktitle = {IEEE Transactions on Information Theory}
}

@article{
 title = {Multipartite Nonlocality in Clifford Networks},
 type = {article},
 year = {2023},
 volume = {130},
 month = {6},
 publisher = {American Physical Society},
 day = {16},
 id = {2cdf606b-7faa-3797-8a01-c41dde4a4f53},
 created = {2025-04-11T23:19:47.123Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T17:35:10.944Z},
 read = {true},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {We adopt a resource-theoretic framework to classify different types of quantum network nonlocality in terms of operational constraints placed on the network. One type of constraint limits the parties to perform local Clifford gates on pure stabilizer states, and we show that quantum network nonlocality cannot emerge in this setting. Yet, if the constraint is relaxed to allow for mixed stabilizer states, then network nonlocality can indeed be obtained. We additionally show that bipartite entanglement is sufficient for generating all forms of quantum network nonlocality when allowing for postselection, a property analogous to the universality of bipartite entanglement for generating all forms of multipartite entangled states.},
 bibtype = {article},
 author = {Gatto Lamas, Amanda and Chitambar, Eric},
 doi = {10.1103/PhysRevLett.130.240802},
 journal = {Physical Review Letters},
 number = {24}
}

@article{
 title = {Reexamination of quantum state transformations with zero communication},
 type = {article},
 year = {2024},
 volume = {109},
 month = {6},
 publisher = {American Physical Society},
 day = {1},
 id = {7287fa47-6973-3445-9c4a-b9c608485e5e},
 created = {2025-04-11T23:19:47.362Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-11T23:20:56.703Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {It is known that general convertibility of bipartite entangled states is not possible to arbitrary error without some classical communication. While some tradeoffs between communication cost and conversion error have been proven, these bounds can be very loose. In particular, there are many cases in which tolerable error might be achievable using zero-communication protocols. In this work we address these cases by deriving the optimal fidelity of pure quantum state conversions under local unitaries as well as local operations and shared randomness. We also use these results to explore catalytic conversions between pure states using zero communication.},
 bibtype = {article},
 author = {George, Ian and Chitambar, Eric},
 doi = {10.1103/PhysRevA.109.062418},
 journal = {Physical Review A},
 number = {6}
}

@article{
 title = {Exact Steering Bound for Two-Qubit Werner States},
 type = {article},
 year = {2024},
 volume = {132},
 month = {6},
 publisher = {American Physical Society},
 day = {21},
 id = {0385ce87-2776-3d90-9d47-b102269cdc3c},
 created = {2025-04-11T23:19:47.397Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-11T23:20:53.166Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Whether positive operator-valued measures (POVMs) provide advantages in demonstrating Bell nonlocality has remained unknown, even in the simple scenario of Einstein-Podolsky-Rosen steering with noisy singlet state, known as Werner states. Here we resolve this long-standing open problem by constructing a local hidden state model for Werner states with any visibility r≤1/2 under general POVMs, thereby closing the so-called Werner gap. This construction is based on an exact measurement compatibility model for the set of all noisy POVMs and also provides a local hidden variable model for a larger range of Werner states than previously known.},
 bibtype = {article},
 author = {Zhang, Yujie and Chitambar, Eric},
 doi = {10.1103/PhysRevLett.132.250201},
 journal = {Physical Review Letters},
 number = {25}
}

@article{
 title = {Reliable quantum memories with unreliable components},
 type = {article},
 year = {2024},
 pages = {032423},
 volume = {110},
 websites = {https://link.aps.org/doi/10.1103/PhysRevA.110.032423},
 month = {9},
 day = {18},
 id = {68d07fba-57ea-32d6-bb8d-94742cf3c7ed},
 created = {2025-04-11T23:19:47.953Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-11T23:20:50.118Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 bibtype = {article},
 author = {Nayak, Anuj K. and Chitambar, Eric and Varshney, Lav R.},
 doi = {10.1103/PhysRevA.110.032423},
 journal = {Physical Review A},
 number = {3}
}

@article{
 title = {Building Multiple Access Channels with a Single Particle},
 type = {article},
 year = {2022},
 volume = {6},
 publisher = {Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften},
 id = {4f4a3703-5a5f-3776-8e5a-3fe9784a02ea},
 created = {2025-04-11T23:19:49.064Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T18:11:37.156Z},
 read = {true},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {A multiple access channel describes a situation in which multiple senders are trying to forward messages to a single receiver using some physical medium. In this paper we consider scenarios in which this medium consists of just a single classical or quantum particle. In the quantum case, the particle can be prepared in a superposition state thereby allowing for a richer family of encoding strategies. To make the comparison between quantum and classical channels precise, we introduce an operational framework in which all possible encoding strategies consume no more than a single particle. We apply this framework to an Nport interferometer experiment in which each party controls a path the particle can traverse. When used for the purpose of communication, this setup embodies a multiple access channel (MAC) built with a single particle. We provide a full characterization of the Nparty classical MACs that can be built from a single particle, and we show that every quantum particle can generate a MAC outside the classical set. To further distinguish the capabilities of a single classical and quantum particle, we relax the locality constraint and allow for joint encodings by subsets of 1 < K ≤ N parties. This generates a richer family of classical MACs whose polytope dimension we compute. We identify a "generalized fingerprinting inequality" as a valid facet for this polytope, and we verify that a quantum particle distributed among N separated parties can violate this inequality even when K = N-1. Connections are drawn between the single-particle framework and multi-level coherence theory. We show that every pure state with K-level coherence can be detected in a semi-device independent manner, with the only assumption being conservation of particle number.},
 bibtype = {article},
 author = {Zhang, Yujie and Chen, Xinan and Chitambar, Eric},
 doi = {10.22331/Q-2022-02-16-653},
 journal = {Quantum}
}

@article{
 title = {Variational Quantum Optimization of Nonlocality in Noisy Quantum Networks},
 type = {article},
 year = {2023},
 keywords = {Design and simulation tools,noisy intermediate-scale quantum (NISQ) algorithms and devices,quantum networking},
 volume = {4},
 publisher = {Institute of Electrical and Electronics Engineers Inc.},
 id = {f48dc44d-f1ae-3347-a029-cdc9bdd476f5},
 created = {2025-04-11T23:19:49.242Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-11T23:20:42.332Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {The noise and complexity inherent to quantum communication networks leads to technical challenges in designing quantum network protocols using classical methods. We address this issue with a hybrid variational quantum optimization (VQO) framework that simulates quantum networks on quantum hardware and optimizes the simulation using differential programming. We maximize nonlocality in noisy quantum networks to showcase our VQO framework. Using a classical simulator, we investigate the noise robustness of quantum nonlocality. Our VQO methods reproduce known results and uncover novel phenomena. We find that maximally entangled states maximize nonlocality in the presence of unital qubit channels, while nonmaximally entangled states can maximize nonlocality in the presence of nonunital qubit channels. Thus, we show VQO to be a practical design tool for quantum networks even when run on a classical simulator. Finally, using IBM quantum computers, we demonstrate that our VQO framework can maximize nonlocality on noisy quantum hardware. In the long term, our VQO techniques show promise of scaling beyond classical approaches and can be deployed on quantum network hardware to optimize network protocols against their inherent noise.},
 bibtype = {article},
 author = {Doolittle, Brian and Bromley, R. Thomas and Killoran, Nathan and Chitambar, Eric},
 doi = {10.1109/TQE.2023.3243849},
 journal = {IEEE Transactions on Quantum Engineering}
}

@article{
 title = {Information carried by a single particle in quantum multiple-access channels},
 type = {article},
 year = {2024},
 volume = {109},
 month = {6},
 publisher = {American Physical Society},
 day = {1},
 id = {50e5332f-f2ce-3875-9551-af5879f171fc},
 created = {2025-04-11T23:19:49.710Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-11T23:20:38.574Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Nonclassical features of quantum systems have the potential to strengthen the way we currently exchange information. In this paper, we explore this enhancement on the most basic level of single particles. To be more precise, we compare how well multiparty information can be transmitted to a single receiver using just one classical or quantum particle. Our approach is based on a multiple-access communication model in which messages can be encoded into a single particle that is coherently distributed across multiple spatial modes. Theoretically, we derive lower bounds on the accessible information in the quantum setting that strictly separate it from the classical scenario. This separation is found whenever there is more than one sender, and also when there is just a single sender who has a shared phase reference with the receiver. When there is only one sender, the separation is impossible without a shared phase reference due to the famous Holevo's bound. Experimentally, we present a proof-of-principle demonstration of such quantum advantage in single-particle communication by implementing a multiport interferometer with messages being encoded along the different trajectories. Specifically, we consider a two-sender communication protocol built by a three-port optical interferometer. In this scenario, the rate sum achievable with a classical particle is upper bounded by one bit, while we experimentally observe a rate sum of 1.0152±0.0034 bits in the quantum setup.},
 bibtype = {article},
 author = {Chen, Xinan and Zhang, Yujie and Winter, Andreas and Lorenz, Virginia O. and Chitambar, Eric},
 doi = {10.1103/PhysRevA.109.062420},
 journal = {Physical Review A},
 number = {6}
}

@article{
 title = {Inferring Quantum Network Topology Using Local Measurements},
 type = {article},
 year = {2023},
 volume = {4},
 month = {10},
 publisher = {American Physical Society},
 day = {1},
 id = {c5331bbe-92af-3034-851f-00d0f36141f2},
 created = {2025-04-11T23:19:51.710Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-11T23:20:33.438Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Statistical correlations that can be generated across the nodes in a quantum network depend crucially on its topology. However, this topological information might not be known a priori, or it may need to be verified. In this paper, we propose an efficient protocol for distinguishing and inferring the topology of a quantum network. We leverage entropic quantities - namely, the von Neumann entropy and the measured mutual information - as well as measurement covariance to uniquely characterize the topology. We show that the entropic quantities are sufficient to distinguish two networks that prepare GHZ states. Moreover, if qubit measurements are available, both entropic quantities and covariance can be used to infer the network topology without state-preparation assumptions. We show that the protocol can be entirely robust to noise and can be implemented via quantum variational optimization. Numerical experiments on both classical simulators and quantum hardware show that covariance is generally more reliable for accurately and efficiently inferring the topology, whereas entropy-based methods are often better at identifying the absence of entanglement in the low-shot regime.},
 bibtype = {article},
 author = {Chen, Daniel T. and Doolittle, Brian and Larson, Jeffrey and Saleem, Zain H. and Chitambar, Eric},
 doi = {10.1103/PRXQuantum.4.040347},
 journal = {PRX Quantum},
 number = {4}
}

@article{
 title = {Entanglement Verification of Hyperentangled Photon Pairs},
 type = {article},
 year = {2022},
 volume = {18},
 month = {11},
 publisher = {American Physical Society},
 day = {1},
 id = {8a9f051f-b0dc-3315-8b21-18ed127a5b67},
 created = {2025-04-12T17:53:42.945Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T18:04:22.009Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {We experimentally investigate the properties of hyperentangled states displaying simultaneous entanglement in multiple degrees of freedom and find that Bell tests beyond the standard Clauser-Horne-Shimony-Holt inequality can reveal a higher-dimensional nature in a device-independent way. Specifically, we show that hyperentangled states possess more than just simultaneous entanglement in separate degrees of freedom but also entanglement in a higher-dimensional Hilbert space. We also verify the steerability of hyperentangled quantum states by steering different photonic degrees of freedom.},
 bibtype = {article},
 author = {Zeitler, Christopher K. and Chapman, Joseph C. and Chitambar, Eric and Kwiat, Paul G.},
 doi = {10.1103/PhysRevApplied.18.054025},
 journal = {Physical Review Applied},
 number = {5}
}

@article{
 title = {Maximal qubit violations of n -locality in star and chain networks},
 type = {article},
 year = {2023},
 volume = {108},
 month = {10},
 publisher = {American Physical Society},
 day = {1},
 id = {1154cbff-cca3-3080-bdaf-8c4a7a9538c2},
 created = {2025-04-12T17:56:25.189Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T18:03:57.166Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {The nonlocal correlations of noisy quantum systems are important for both understanding nature and developing quantum technology. We consider the correlations of star and chain quantum networks in which noisy entanglement sources are measured by nonsignaling parties. We derive the necessary and sufficient conditions for when a broad family of star and chain n-locality inequalities achieve their maximal quantum violation assuming that each party's dichotomic observables are separable across qudit systems. When pairs of local dichotomic observables are considered on qubit systems, we derive maximal n-local violations that are larger and more robust to noise than the maximal n-locality violations reported previously. To obtain these larger values, we consider observables that we have not found in previous studies. Thus, we gain insights into self-testing entanglement sources and measurements in star and chain networks.},
 bibtype = {article},
 author = {Doolittle, Brian and Chitambar, Eric},
 doi = {10.1103/PhysRevA.108.042409},
 journal = {Physical Review A},
 number = {4}
}

@article{
 title = {Cone-restricted information theory},
 type = {article},
 year = {2024},
 keywords = {conic programming,convex geometry,quantum entropies,quantum information theory},
 volume = {57},
 month = {6},
 publisher = {Institute of Physics},
 day = {28},
 id = {c39258e0-d504-324c-8855-3f591d4dda3f},
 created = {2025-04-12T17:56:44.686Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T18:03:24.095Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {The max-relative entropy and the conditional min-entropy of a quantum state plays a central role in one-shot and zero-error quantum information theory. One attractive feature of this quantity is that it can be expressed as an optimization over the cone of positive semidefinite operators. Recently, it was shown that when replacing this cone with the cone of separable operators, a new type of conditional min-entropy emerges that admits an operational interpretation in terms of communicating classical information over a quantum channel. In this work, we explore more deeply the idea of building information-theoretic quantities from different base cones and determine which results in quantum information theory rely upon the positive semidefinite cone and which can be generalized. In terms of asymptotic information processing, we find that the standard equipartition properties break down if a given cone fails to approximate the positive semidefinite cone sufficiently well. We also show that the near-equivalence of the smooth max and Hartley entropies breaks down in this setting. We present parallel results for the extended conditional min-entropy, which requires extending the notion of k-superpositive channels to superchannels. On the other hand, we show that for classical-quantum states the separable cone is sufficient to re-cover the asymptotic theory, thereby drawing a strong distinction between the fully and partial quantum settings. We also present operational uses of this framework. We show that the cone restricted min-entropy of a Choi operator captures a measure of entanglement-assisted noiseless classical communication using restricted measurements. We also introduce a novel min-entropy-like quantity that captures the conditions for when one quantum channel can be transformed into another using bistochastic pre-processing. Lastly, we relate this framework to general conic norms and their non-additivity. Throughout this work, we concretely study generalized entropies in resource theories that capture locality and resource theories of coherence/Abelian symmetries.},
 bibtype = {article},
 author = {George, Ian and Chitambar, Eric},
 doi = {10.1088/1751-8121/ad52d5},
 journal = {Journal of Physics A: Mathematical and Theoretical},
 number = {26}
}

@article{
 title = {Process-optimized phase-covariant quantum cloning},
 type = {article},
 year = {2022},
 volume = {106},
 month = {8},
 publisher = {American Physical Society},
 day = {1},
 id = {71a72245-5ac8-3607-a817-ba8988e88461},
 created = {2025-04-12T18:01:03.461Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T18:04:26.628Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {After the appearance of the no-cloning theorem, approximate quantum cloning machines (QCMs) has become a well-studied subject in quantum information theory. Among several measures to quantify the performance of a QCM, single-qudit fidelity and global fidelity have been most widely used. In this paper we compute the optimal global fidelity for phase-covariant cloning machines via semidefinite programming optimization, thereby completing a remaining gap in the previous results on QCMs. We also consider optimal simulations of the cloning and transpose cloning map, both by a direct optimization and by a composition of component-wise optimal QCMs. For the cloning map the composition method is suboptimal whereas for the transpose cloning map the method is asymptotically optimal.},
 bibtype = {article},
 author = {Kim, Chloe and Chitambar, Eric},
 doi = {10.1103/PhysRevA.106.022405},
 journal = {Physical Review A},
 number = {2}
}

@article{
 title = {Quantum telescopy clock games},
 type = {article},
 year = {2022},
 volume = {106},
 month = {9},
 publisher = {American Physical Society},
 day = {1},
 id = {ebbc76a5-436e-3500-a6a6-9e0e5183a6e0},
 created = {2025-04-12T18:01:03.649Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T18:04:31.535Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {We consider the clock game-a task formulated in the framework of quantum information theory - that can be used to improve the existing schemes of quantum-enhanced telescopy. The problem of learning when a stellar photon reaches a telescope is translated into an abstract game, which we call the clock game. A winning strategy is provided that involves performing a quantum non-demolition measurement that verifies which stellar spatio-temporal modes are occupied by a photon without disturbing the phase information. We prove tight lower bounds on the entanglement cost needed to win the clock game, with the amount of necessary entangled bits equaling the number of time bins being distinguished. This lower bound on the entanglement cost applies to any telescopy protocol that aims to nondestructively extract the time bin information of an incident photon through local measurements, and our result implies that the protocol of Khabiboulline et al. [Phys. Rev. Lett. 123, 070504 (2019)0031-900710.1103/PhysRevLett.123.070504] is optimal in terms of entanglement consumption. The full task of the phase extraction is also considered, and we show that the quantum Fisher information of the stellar phase can be achieved by local measurements and shared entanglement without the necessity of nonlinear optical operations. The optimal phase measurement is achieved asymptotically with increasing number of ancilla qubits, whereas a single qubit pair is required if nonlinear operations are allowed.},
 bibtype = {article},
 author = {Czupryniak, Robert and Chitambar, Eric and Steinmetz, John and Jordan, Andrew N.},
 doi = {10.1103/PhysRevA.106.032424},
 journal = {Physical Review A},
 number = {3}
}

@article{
 title = {Certifying the classical simulation cost of a quantum channel},
 type = {article},
 year = {2021},
 volume = {3},
 month = {12},
 publisher = {American Physical Society},
 day = {1},
 id = {12f24a7c-b1a5-339f-8f03-334ad0e1dbc5},
 created = {2025-04-12T18:01:04.723Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T18:04:35.993Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {A fundamental objective in quantum information science is to determine the cost in classical resources of simulating a particular quantum system. The classical simulation cost is quantified by the signaling dimension which specifies the minimum amount of classical communication needed to perfectly simulate a channel's input-output correlations when unlimited shared randomness is held between encoder and decoder. This paper provides a collection of device-independent tests that place lower and upper bounds on the signaling dimension of a channel. Among them, a single family of tests is shown to determine when a noisy classical channel can be simulated using an amount of communication strictly less than either its input or its output alphabet size. In addition, a family of eight signaling dimension witnesses is presented that completely characterize when any four-outcome measurement channel, such as a Bell measurement, can be simulated using one communication bit and shared randomness. Finally, we bound the signaling dimension for all partial replacer channels in d dimensions. The bounds are found to be tight for the special case of the erasure channel.},
 bibtype = {article},
 author = {Doolittle, Brian and Chitambar, Eric},
 doi = {10.1103/PhysRevResearch.3.043073},
 journal = {Physical Review Research},
 number = {4}
}

@article{
 title = {Hierarchy of multipartite correlations based on concentratable entanglement},
 type = {article},
 year = {2024},
 volume = {6},
 month = {4},
 publisher = {American Physical Society},
 day = {1},
 id = {0655f4a8-c093-34eb-84d3-c3c8da4331f4},
 created = {2025-04-12T18:01:06.082Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T18:03:26.987Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Multipartite entanglement is one of the hallmarks of quantum mechanics and is central to quantum information processing. In this work we show that concentratable entanglement (CE), an operationally motivated entanglement measure, induces a hierarchy upon pure states from which different entanglement structures can be experimentally certified. In particular, we find that nearly all genuine multipartite entangled states can be verified through the CE. Interestingly, GHZ states prove to be far from maximally entangled according to this measure. Instead we find the exact maximal value and corresponding states for up to 18 qubits and show that these correspond to extremal quantum error correcting codes. The latter allows us to unravel a deep connection between CE and coding theory. Finally, our results also offer an alternative proof, on up to 31 qubits, that absolutely maximally entangled states do not exist.},
 bibtype = {article},
 author = {Schatzki, Louis and Liu, Guangkuo and Cerezo, M. and Chitambar, Eric},
 doi = {10.1103/PhysRevResearch.6.023019},
 journal = {Physical Review Research},
 number = {2}
}

@article{
 title = {Incompatibility as a Resource for Programmable Quantum Instruments},
 type = {article},
 year = {2024},
 volume = {5},
 month = {1},
 publisher = {American Physical Society},
 day = {1},
 id = {37d28aa7-b884-3fd7-b908-383e76f00f66},
 created = {2025-04-12T18:01:07.654Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T18:03:30.443Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Quantum instruments represent the most general type of quantum measurement, as they incorporate processes with both classical and quantum outputs. In many scenarios, it may be desirable to have some "on-demand"device that is capable of implementing one of many possible instruments whenever the experimenter desires. We refer to such objects as programmable instrument devices (PIDs), and this paper studies PIDs from a resource-theoretic perspective. A physically important class of PIDs are those that do not require quantum memories to implement, and these are naturally "free"in this resource theory. Additionally, these free objects correspond precisely to the class of unsteerable channel assemblages in the study of channel steering. The traditional notion of measurement incompatibility emerges as a resource in this theory since any PID controlling an incompatible family of instruments requires a quantum memory to build. We identify an incompatibility preorder between PIDs based on whether one can be transformed into another using processes that do not require additional quantum memories. Necessary and sufficient conditions are derived for when such transformations are possible based on how well certain guessing games can be played using a given PID. Ultimately our results provide an operational characterization of incompatibility, and they offer semi-device-independent tests for incompatibility in the most general types of quantum instruments.},
 bibtype = {article},
 author = {Ji, Kaiyuan and Chitambar, Eric},
 doi = {10.1103/PRXQuantum.5.010340},
 journal = {PRX Quantum},
 number = {1}
}

@article{
 title = {The Round Complexity of Local Operations and Classical Communication (LOCC) in Random-Party Entanglement Distillation},
 type = {article},
 year = {2023},
 volume = {7},
 publisher = {Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften},
 id = {08d505c5-be9f-3f5c-96ee-3822c9c0d860},
 created = {2025-04-12T18:01:10.179Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T18:04:06.297Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {A powerful operational paradigm for distributed quantum information processing involves manipulating pre-shared entanglement by local operations and classical communication (LOCC). The LOCC round complexity of a given task describes how many rounds of classical communication are needed to complete the task. Despite some results separating one-round versus two-round protocols, very little is known about higher round complexities. In this paper, we revisit the task of one-shot random-party entanglement distillation as a way to highlight some interesting features of LOCC round complexity. We first show that for random-party distillation in three qubits, the number of communication rounds needed in an optimal protocol depends on the entanglement measure used; for the same fixed state some entanglement measures need only two rounds to maximize whereas others need an unbounded number of rounds. In doing so, we construct a family of LOCC instruments that require an unbounded number of rounds to implement. We then prove explicit tight lower bounds on the LOCC round number as a function of distillation success probability. Our calculations show that the original W-state random distillation protocol by Fortescue and Lo is essentially optimal in terms of round complexity.},
 bibtype = {article},
 author = {Liu, Guangkuo and George, Ian and Chitambar, Eric},
 doi = {10.22331/Q-2023-09-07-1104},
 journal = {Quantum}
}

@article{
 title = {Quantum Bell nonlocality as a form of entanglement},
 type = {article},
 year = {2021},
 volume = {104},
 month = {11},
 publisher = {American Physical Society},
 day = {1},
 id = {3149dae2-6486-3227-866c-8d53a9798d7b},
 created = {2025-04-12T18:01:33.606Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T18:04:40.733Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Bell nonlocality describes a manifestation of quantum mechanics that cannot be explained by any local hidden variable model. Its origin lies in the nature of quantum entanglement, although understanding the precise relationship between nonlocality and entanglement has been a notorious open problem. In this paper, we develop a dynamical framework in which quantum Bell nonlocality emerges as a special form of entanglement and both are unified as resources under local operations and classical communication (LOCC). Our framework is built on the notion of classical and quantum processes, which are defined as channels that map elements between specific intervals in space and time. Entanglement is identified as a process that cannot be generated by LOCC while Bell nonlocality is the subset of these processes that have an instantaneous input-to-output delay time. LOCC preprocessing is a natural set of free operations in this theory, thereby providing previous nonlocality activation results a clear resource-theoretic foundation. We provide a systematic method to quantify the Bell nonlocality of a bipartite quantum channel. It is shown that both the relative entropy and the max relative entropy of nonlocality are nonadditive for a family of bipartite classical channels. This family includes the channel obtained when using the singlet state to maximally violate the CHSH inequality. We also find that the regularized relative entropy of Bell nonlocality provides an upper bound on the asymptotic rate of converting (i.e., simulating) many copies of one classical instantaneous resource to another.},
 bibtype = {article},
 author = {Chitambar, Eric and Gour, Gilad and Sengupta, Kuntal and Zibakhsh, Rana},
 doi = {10.1103/PhysRevA.104.052208},
 journal = {Physical Review A},
 number = {5}
}

@article{
 title = {Entanglement of assistance in three-qubit systems},
 type = {article},
 year = {2021},
 volume = {103},
 month = {3},
 publisher = {American Physical Society},
 day = {1},
 id = {30a20f92-add7-389f-b1cd-e8064e0fe4a1},
 created = {2025-04-12T18:06:35.114Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-12T18:06:50.194Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {The entanglement of assistance quantifies the amount of entanglement that can be concentrated among a group of spatially separated parties using the assistance of some auxiliary system. In this paper we study the entanglement of assistance in the simplest scenario of three qubits. We consider how much entanglement is lost when the helper party becomes uncoupled by local measurement and classical communication. For three-qubit pure states, it is found that lossless decoupling is always possible when entanglement is quantified by the maximum probability of locally generating a Bell state. However, with respect to most other entanglement measures, such as concurrence and entanglement entropy, a lossless decoupling of the helper is possible only for a special family of states that we fully characterize.},
 bibtype = {article},
 author = {Pollock, Klee and Wang, Ge and Chitambar, Eric},
 doi = {10.1103/PhysRevA.103.032428},
 journal = {Physical Review A},
 number = {3}
}

@article{
 title = {Tensor rank and other multipartite entanglement measures of graph states},
 type = {article},
 year = {2024},
 volume = {110},
 month = {9},
 publisher = {American Physical Society},
 day = {1},
 id = {d0f4460c-c596-3010-a7e0-e5cf875cebc3},
 created = {2025-04-13T16:59:49.510Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-13T16:59:58.743Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Graph states play an important role in quantum information theory through their connection to measurement-based computing and error correction. Prior work revealed elegant connections between the graph structure of these states and their multipartite entanglement. We continue this line of investigation by identifying additional entanglement properties for certain types of graph states. From the perspective of tensor theory, we tighten both upper and lower bounds on the tensor rank of odd ring states (|R2n+1)) to read 2n+1≤rank(|R2n+1))≤3×2n-1. Next we show that several multipartite extensions of bipartite entanglement measures are dichotomous for graph states based on the connectivity of the corresponding graph. Finally, we give a simple graph rule for computing the n-tangle τn.},
 bibtype = {article},
 author = {Schatzki, Louis and Ma, Linjian and Solomonik, Edgar and Chitambar, Eric},
 doi = {10.1103/PhysRevA.110.032409},
 journal = {Physical Review A},
 number = {3}
}

@article{
 title = {Dynamical resource theory of quantum coherence},
 type = {article},
 year = {2020},
 volume = {2},
 month = {6},
 publisher = {American Physical Society},
 day = {8},
 id = {9b81b5f6-a9d1-393b-a18b-6671b35346e4},
 created = {2025-04-13T17:02:45.760Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-04-13T17:03:02.550Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {Decoherence is all around us. Every quantum system that interacts with the environment is doomed to decohere. While preserving quantum coherence is a major challenge faced in quantum technologies, the potential benefits for information processing are very promising since coherence can lead to various operational advantages, such as in quantum algorithms. Hence, much work has been devoted in recent years to quantify the coherence present in a system. In the present paper, we formulate the quantum resource theory of dynamical coherence. The underlying physical principle we follow is that the free dynamical objects are those that neither store nor output coherence. This leads us to identify classical channels as the free elements in this theory. Consequently, even the quantum identity channel is not free as all physical systems undergo decoherence and hence, the preservation of coherence should be considered a resource. The maximally coherent channel is then the quantum Fourier transform because of its abillity to preserve entanglement and generate maximal coherence from nothing. In our work, we introduce four different types of free superchannels (analogous to MIO, DIO, IO, and SIO) and discuss in detail two of them, namely, dephasing-covariant incoherent superchannels (DISC), maximally incoherent superchannels (MISC). The latter consists of all superchannels that do not generate non-classical channels from classical ones. We quantify dynamical coherence using channel-divergence-based monotones for MISC and DISC. We show that some of these monotones have operational interpretations as the exact, the approximate, and the liberal coherence cost of a quantum channel. Moreover, we prove that the liberal asymptotic cost of a channel is equal to a new type of regularized relative entropy. Finally, we show that the conversion distance between two channels under MISC and DISC can be computed using a semidefinite program (SDP).},
 bibtype = {article},
 author = {Saxena, Gaurav and Chitambar, Eric and Gour, Gilad},
 doi = {10.1103/PhysRevResearch.2.023298},
 journal = {Physical Review Research},
 number = {2}
}

@article{
 title = {Random Distillation Protocols in Long Baseline Telescopy},
 type = {article},
 year = {2025},
 volume = {134},
 month = {5},
 publisher = {American Physical Society},
 day = {2},
 id = {19d57ebf-f977-3374-bb32-888215d22e47},
 created = {2025-05-13T13:04:04.890Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-05-13T13:04:19.198Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 abstract = {In quantum-enhanced astronomical imaging, multiple distant apertures work together by utilizing quantum resources distributed from a central server. Our findings suggest that preprocessing the stellar light received by all telescopes can improve imaging performance without increasing resource consumption. The preprocessing leverages weak quantum measurements and modifies random-party entanglement distillation protocols from quantum information science. Intuitively, this approach allows us to collapse the stellar light that is originally coherent between all telescopes to one pair of telescopes with probability arbitrarily close to one. The central server can then distribute entanglement solely to the pair of telescopes receiving a photon, thereby enhancing the efficiency of resource utilization. We discuss two types of resources that benefit from this preprocessing: shared entanglement and a shared reference frame.},
 bibtype = {article},
 author = {Wang, Yunkai and Chitambar, Eric},
 doi = {10.1103/PhysRevLett.134.170801},
 journal = {Physical Review Letters},
 number = {17}
}

@article{
 title = {No-Go Theorems for Universal Entanglement Purification},
 type = {article},
 year = {2025},
 pages = {190803},
 volume = {134},
 websites = {https://link.aps.org/doi/10.1103/PhysRevLett.134.190803},
 month = {5},
 day = {13},
 id = {10898382-50d4-3de6-8710-9901a12f1cee},
 created = {2025-05-14T14:45:58.217Z},
 file_attached = {true},
 profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},
 last_modified = {2025-05-14T14:46:05.189Z},
 read = {false},
 starred = {false},
 authored = {true},
 confirmed = {false},
 hidden = {false},
 private_publication = {false},
 bibtype = {article},
 author = {Zang, Allen and Chen, Xinan and Chitambar, Eric and Suchara, Martin and Zhong, Tian},
 doi = {10.1103/PhysRevLett.134.190803},
 journal = {Physical Review Letters},
 number = {19}
}\">\n            <i class=\"fa fa-download fa-fw\"></i> Download BibTeX\n          </a>\n        </li>\n        <li>\n          <a href=\"//bibbase.org/rss?bib=\">\n            <i class=\"fa fa-rss fa-fw\"></i> RSS Feed\n          </a>\n          </li>\n      </ul>\n      </li>\n\n      \n\n\n      \n    </ul>\n\n\n    <div class=\"alert alert-success bibbase_msg\" id=\"bibbase_msg_embed\"\n         style=\"display: none;\">\n\n      Excellent! Next you can\n      <a href=\"/network/register?next=/network/newSiteFromTemplate%3Fbiburl=\"\n      >create a new website with this list</a>, or\n      embed it in an existing web page by copying &amp; pasting\n      any of the following snippets.\n\n      <div style=\"text-align: left; margin-top: 1em;\">\n        <strong>JavaScript</strong>\n        <span class=\"comment recommended\">(easiest)</span>\n        <div class=\"well well-small\">\n          <code>\n            &lt;script src=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0?jsonp=1&amp;jsonp=1\"&gt;&lt;/script&gt;\n          </code>\n        </div>\n\n        <strong>PHP</strong>\n        <div class=\"well well-small\">\n          <code>\n            &lt;?php\n            $contents = file_get_contents(\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0?jsonp=1\");\n            print_r($contents);\n            ?&gt;\n          </code>\n        </div>\n\n        <strong>iFrame</strong>\n        <span class=\"comment\">(not recommended)</span>\n        <div class=\"well well-small\">\n          <code>\n            &lt;iframe src=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0?jsonp=1\"&gt;&lt;/iframe&gt;\n          </code>\n        </div>\n\n        <p>\n          For more details see the <a href=\"//bibbase.org/help\">documention</a>.\n        </p>\n      </div>\n    </div>\n\n    <div class=\"alert alert-success bibbase_msg\" id=\"bibbase_msg_preview\"\n         style=\"display: none;\">\n\n      This is a preview! To use this list on your own web site\n      or create a new web site from it,\n      <a href=\"/network/register?next=/network/newAccountWithFile%3FfileId=\"\n      >create a free account</a>. The file will be added\n      and you will be able to edit it in the File Manager.\n      We will show you instructions once you've created your account.\n    </div>\n\n    <div class=\"alert alert-warning bibbase_msg\" id=\"bibbase_msg_mendeley1\"\n         style=\"display: none;\">\n\n      <p>To the site owner:</p>\n\n      <p><strong>Action required!</strong> Mendeley is changing its\n        API. In order to keep using Mendeley with BibBase past April\n        14th, you need to:\n        <ol>\n          <li>renew the authorization for BibBase on Mendeley, and</li>\n          <li>update the BibBase URL\n            in your page the same way you did when you initially set up\n            this page.\n          </li>\n        </ol>\n      </p>\n\n      <p>\n        <a href=\"http://bibbase.org/cgi-bin/mendeley2/get.py\">\n          <i class=\"fa fa-angle-double-right\"></i>\n          Fix it now</a>\n      </p>\n    </div>\n\n  </div>\n\n\n  <div id=\"bibbase_body\">\n    \n  \n  <div class=\"bibbase_group_whole\" id=\"group_2025\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2025')\"\n      onkeypress=\"toggleGroup('group_2025')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2025</span>\n      <span class=\"bibbase_group_count\">\n        \n        (2)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"wang-chitambar-randomdistillationprotocolsinlongbaselinetelescopy-2025\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/03b6b4b0-2c7d-c0f7-655e-32a10b1dccbf/Wang_2025_Random_Distillation_Protocols_in_Long_Baseline_T_1.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'wang-chitambar-randomdistillationprotocolsinlongbaselinetelescopy-2025', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/03b6b4b0-2c7d-c0f7-655e-32a10b1dccbf/Wang_2025_Random_Distillation_Protocols_in_Long_Baseline_T_1.pdf.pdf', event);\">\n    Random Distillation Protocols in Long Baseline Telescopy.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Wang,  Y.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 134(17). 5 2025.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/03b6b4b0-2c7d-c0f7-655e-32a10b1dccbf/Wang_2025_Random_Distillation_Protocols_in_Long_Baseline_T_1.pdf.pdf\"\n     onclick=\"log_download('wang-chitambar-randomdistillationprotocolsinlongbaselinetelescopy-2025', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/03b6b4b0-2c7d-c0f7-655e-32a10b1dccbf/Wang_2025_Random_Distillation_Protocols_in_Long_Baseline_T_1.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Random Distillation Protocols in Long Baseline Telescopy [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.134.170801\"\n     onclick=\"log_download('wang-chitambar-randomdistillationprotocolsinlongbaselinetelescopy-2025', 'http://doi.org/10.1103/PhysRevLett.134.170801', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/wang-chitambar-randomdistillationprotocolsinlongbaselinetelescopy-2025\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('wang-chitambar-randomdistillationprotocolsinlongbaselinetelescopy-2025')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Random Distillation Protocols in Long Baseline Telescopy},\n type = {article},\n year = {2025},\n volume = {134},\n month = {5},\n publisher = {American Physical Society},\n day = {2},\n id = {19d57ebf-f977-3374-bb32-888215d22e47},\n created = {2025-05-13T13:04:04.890Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-05-13T13:04:19.198Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {In quantum-enhanced astronomical imaging, multiple distant apertures work together by utilizing quantum resources distributed from a central server. Our findings suggest that preprocessing the stellar light received by all telescopes can improve imaging performance without increasing resource consumption. The preprocessing leverages weak quantum measurements and modifies random-party entanglement distillation protocols from quantum information science. Intuitively, this approach allows us to collapse the stellar light that is originally coherent between all telescopes to one pair of telescopes with probability arbitrarily close to one. The central server can then distribute entanglement solely to the pair of telescopes receiving a photon, thereby enhancing the efficiency of resource utilization. We discuss two types of resources that benefit from this preprocessing: shared entanglement and a shared reference frame.},\n bibtype = {article},\n author = {Wang, Yunkai and Chitambar, Eric},\n doi = {10.1103/PhysRevLett.134.170801},\n journal = {Physical Review Letters},\n number = {17}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  In quantum-enhanced astronomical imaging, multiple distant apertures work together by utilizing quantum resources distributed from a central server. Our findings suggest that preprocessing the stellar light received by all telescopes can improve imaging performance without increasing resource consumption. The preprocessing leverages weak quantum measurements and modifies random-party entanglement distillation protocols from quantum information science. Intuitively, this approach allows us to collapse the stellar light that is originally coherent between all telescopes to one pair of telescopes with probability arbitrarily close to one. The central server can then distribute entanglement solely to the pair of telescopes receiving a photon, thereby enhancing the efficiency of resource utilization. We discuss two types of resources that benefit from this preprocessing: shared entanglement and a shared reference frame.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"zang-chen-chitambar-suchara-zhong-nogotheoremsforuniversalentanglementpurification-2025\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/6bbfbbda-957d-437b-4a5e-eb3aac99f257/Zang_2025_No_Go_Theorems_for_Universal_Entanglement_Purifica.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'zang-chen-chitambar-suchara-zhong-nogotheoremsforuniversalentanglementpurification-2025', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/6bbfbbda-957d-437b-4a5e-eb3aac99f257/Zang_2025_No_Go_Theorems_for_Universal_Entanglement_Purifica.pdf.pdf', event);\">\n    No-Go Theorems for Universal Entanglement Purification.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Zang,  A.; Chen,  X.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Suchara,  M.;  and Zhong,  T.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 134(19): 190803. 5 2025.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/6bbfbbda-957d-437b-4a5e-eb3aac99f257/Zang_2025_No_Go_Theorems_for_Universal_Entanglement_Purifica.pdf.pdf\"\n     onclick=\"log_download('zang-chen-chitambar-suchara-zhong-nogotheoremsforuniversalentanglementpurification-2025', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/6bbfbbda-957d-437b-4a5e-eb3aac99f257/Zang_2025_No_Go_Theorems_for_Universal_Entanglement_Purifica.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"No-Go Theorems for Universal Entanglement Purification [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n  <a href=\"https://link.aps.org/doi/10.1103/PhysRevLett.134.190803\"\n     onclick=\"log_download('zang-chen-chitambar-suchara-zhong-nogotheoremsforuniversalentanglementpurification-2025', 'https://link.aps.org/doi/10.1103/PhysRevLett.134.190803', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/link.svg\"\n\t     alt=\"No-Go Theorems for Universal Entanglement Purification [link]\"\n       title=\"Website\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Website</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.134.190803\"\n     onclick=\"log_download('zang-chen-chitambar-suchara-zhong-nogotheoremsforuniversalentanglementpurification-2025', 'http://doi.org/10.1103/PhysRevLett.134.190803', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/zang-chen-chitambar-suchara-zhong-nogotheoremsforuniversalentanglementpurification-2025\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('zang-chen-chitambar-suchara-zhong-nogotheoremsforuniversalentanglementpurification-2025')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {No-Go Theorems for Universal Entanglement Purification},\n type = {article},\n year = {2025},\n pages = {190803},\n volume = {134},\n websites = {https://link.aps.org/doi/10.1103/PhysRevLett.134.190803},\n month = {5},\n day = {13},\n id = {10898382-50d4-3de6-8710-9901a12f1cee},\n created = {2025-05-14T14:45:58.217Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-05-14T14:46:05.189Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n bibtype = {article},\n author = {Zang, Allen and Chen, Xinan and Chitambar, Eric and Suchara, Martin and Zhong, Tian},\n doi = {10.1103/PhysRevLett.134.190803},\n journal = {Physical Review Letters},\n number = {19}\n}</pre>\n</div>\n\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2024\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2024')\"\n      onkeypress=\"toggleGroup('group_2024')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2024</span>\n      <span class=\"bibbase_group_count\">\n        \n        (9)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"chitambar-leditzky-onthedualityofteleportationanddensecoding-2024\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/03dd6130-0f22-7da7-7bc9-e067fc23b4ef/Chitambar_2024_On_the_Duality_of_Teleportation_and_Dense_C_1.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'chitambar-leditzky-onthedualityofteleportationanddensecoding-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/03dd6130-0f22-7da7-7bc9-e067fc23b4ef/Chitambar_2024_On_the_Duality_of_Teleportation_and_Dense_C_1.pdf.pdf', event);\">\n    On the Duality of Teleportation and Dense Coding.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Leditzky,  F.\n</span>\n\n  \n\n</span>\n\n  <i>IEEE Transactions on Information Theory</i>, 70(5): 3529-3537. 5 2024.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/03dd6130-0f22-7da7-7bc9-e067fc23b4ef/Chitambar_2024_On_the_Duality_of_Teleportation_and_Dense_C_1.pdf.pdf\"\n     onclick=\"log_download('chitambar-leditzky-onthedualityofteleportationanddensecoding-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/03dd6130-0f22-7da7-7bc9-e067fc23b4ef/Chitambar_2024_On_the_Duality_of_Teleportation_and_Dense_C_1.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"On the Duality of Teleportation and Dense Coding [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n  <a href=\"https://ieeexplore.ieee.org/document/10315956/\"\n     onclick=\"log_download('chitambar-leditzky-onthedualityofteleportationanddensecoding-2024', 'https://ieeexplore.ieee.org/document/10315956/', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/link.svg\"\n\t     alt=\"On the Duality of Teleportation and Dense Coding [link]\"\n       title=\"Website\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Website</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1109/TIT.2023.3331821\"\n     onclick=\"log_download('chitambar-leditzky-onthedualityofteleportationanddensecoding-2024', 'http://doi.org/10.1109/TIT.2023.3331821', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-leditzky-onthedualityofteleportationanddensecoding-2024\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-leditzky-onthedualityofteleportationanddensecoding-2024')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {On the Duality of Teleportation and Dense Coding},\n type = {article},\n year = {2024},\n pages = {3529-3537},\n volume = {70},\n websites = {https://ieeexplore.ieee.org/document/10315956/},\n month = {5},\n publisher = {Institute of Electrical and Electronics Engineers Inc.},\n id = {0c5f12d2-17dc-3ba3-a6da-2b7c3897488e},\n created = {2025-04-11T19:50:02.491Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-13T16:53:53.779Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Quantum teleportation is a quantum communication primitive that allows a long-distance quantum channel to be built using pre-shared entanglement and one-way classical communication. However, the quality of the established channel crucially depends on the quality of the pre-shared entanglement. In this work, we revisit the problem of using noisy entanglement for the task of teleportation. We first show how this problem can be rephrased as a state discrimination problem. In this picture, a quantitative duality between teleportation and dense coding emerges in which every Alice-to-Bob teleportation protocol can be repurposed as a Bob-to-Alice dense coding protocol, and the quality of each protocol can be measured by the success probability in the same state discrimination problem. One of our main results provides a complete characterization of the states that offer no advantage in one-way teleportation protocols over classical states, thereby offering a new and intriguing perspective on the long-standing open problem of identifying such states. This also yields a new proof of the known fact that bound entangled states cannot exceed the classical teleportation threshold. Moreover, our established duality between teleportation and dense coding can be used to show that the exact same states are unable to provide a non-classical advantage for dense coding as well. We also discuss the duality from a communication capacity point of view, deriving upper and lower bounds on the accessible information of a dense coding protocol in terms of the fidelity of its associated teleportation protocol. A corollary of this discussion is a simple proof of the previously established fact that bound entangled states do not provide any advantage in dense coding.},\n bibtype = {article},\n author = {Chitambar, Eric and Leditzky, Felix},\n doi = {10.1109/TIT.2023.3331821},\n journal = {IEEE Transactions on Information Theory},\n number = {5}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Quantum teleportation is a quantum communication primitive that allows a long-distance quantum channel to be built using pre-shared entanglement and one-way classical communication. However, the quality of the established channel crucially depends on the quality of the pre-shared entanglement. In this work, we revisit the problem of using noisy entanglement for the task of teleportation. We first show how this problem can be rephrased as a state discrimination problem. In this picture, a quantitative duality between teleportation and dense coding emerges in which every Alice-to-Bob teleportation protocol can be repurposed as a Bob-to-Alice dense coding protocol, and the quality of each protocol can be measured by the success probability in the same state discrimination problem. One of our main results provides a complete characterization of the states that offer no advantage in one-way teleportation protocols over classical states, thereby offering a new and intriguing perspective on the long-standing open problem of identifying such states. This also yields a new proof of the known fact that bound entangled states cannot exceed the classical teleportation threshold. Moreover, our established duality between teleportation and dense coding can be used to show that the exact same states are unable to provide a non-classical advantage for dense coding as well. We also discuss the duality from a communication capacity point of view, deriving upper and lower bounds on the accessible information of a dense coding protocol in terms of the fidelity of its associated teleportation protocol. A corollary of this discussion is a simple proof of the previously established fact that bound entangled states do not provide any advantage in dense coding.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"george-chitambar-reexaminationofquantumstatetransformationswithzerocommunication-2024\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/63ab2c67-2f71-1dcf-07e0-672d4dacad37/Chitambar_2024_Reexamination_of_quantum_state_transformation.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'george-chitambar-reexaminationofquantumstatetransformationswithzerocommunication-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/63ab2c67-2f71-1dcf-07e0-672d4dacad37/Chitambar_2024_Reexamination_of_quantum_state_transformation.pdf.pdf', event);\">\n    Reexamination of quantum state transformations with zero communication.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  George,  I.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 109(6). 6 2024.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/63ab2c67-2f71-1dcf-07e0-672d4dacad37/Chitambar_2024_Reexamination_of_quantum_state_transformation.pdf.pdf\"\n     onclick=\"log_download('george-chitambar-reexaminationofquantumstatetransformationswithzerocommunication-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/63ab2c67-2f71-1dcf-07e0-672d4dacad37/Chitambar_2024_Reexamination_of_quantum_state_transformation.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Reexamination of quantum state transformations with zero communication [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.109.062418\"\n     onclick=\"log_download('george-chitambar-reexaminationofquantumstatetransformationswithzerocommunication-2024', 'http://doi.org/10.1103/PhysRevA.109.062418', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/george-chitambar-reexaminationofquantumstatetransformationswithzerocommunication-2024\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('george-chitambar-reexaminationofquantumstatetransformationswithzerocommunication-2024')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Reexamination of quantum state transformations with zero communication},\n type = {article},\n year = {2024},\n volume = {109},\n month = {6},\n publisher = {American Physical Society},\n day = {1},\n id = {7287fa47-6973-3445-9c4a-b9c608485e5e},\n created = {2025-04-11T23:19:47.362Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-11T23:20:56.703Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {It is known that general convertibility of bipartite entangled states is not possible to arbitrary error without some classical communication. While some tradeoffs between communication cost and conversion error have been proven, these bounds can be very loose. In particular, there are many cases in which tolerable error might be achievable using zero-communication protocols. In this work we address these cases by deriving the optimal fidelity of pure quantum state conversions under local unitaries as well as local operations and shared randomness. We also use these results to explore catalytic conversions between pure states using zero communication.},\n bibtype = {article},\n author = {George, Ian and Chitambar, Eric},\n doi = {10.1103/PhysRevA.109.062418},\n journal = {Physical Review A},\n number = {6}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  It is known that general convertibility of bipartite entangled states is not possible to arbitrary error without some classical communication. While some tradeoffs between communication cost and conversion error have been proven, these bounds can be very loose. In particular, there are many cases in which tolerable error might be achievable using zero-communication protocols. In this work we address these cases by deriving the optimal fidelity of pure quantum state conversions under local unitaries as well as local operations and shared randomness. We also use these results to explore catalytic conversions between pure states using zero communication.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"zhang-chitambar-exactsteeringboundfortwoqubitwernerstates-2024\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/34968950-2132-0545-73a7-c55ab0bcae63/Chitambar_2024_Exact_Steering_Bound_for_Two_Qubit_Werner_Sta.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'zhang-chitambar-exactsteeringboundfortwoqubitwernerstates-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/34968950-2132-0545-73a7-c55ab0bcae63/Chitambar_2024_Exact_Steering_Bound_for_Two_Qubit_Werner_Sta.pdf.pdf', event);\">\n    Exact Steering Bound for Two-Qubit Werner States.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Zhang,  Y.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 132(25). 6 2024.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/34968950-2132-0545-73a7-c55ab0bcae63/Chitambar_2024_Exact_Steering_Bound_for_Two_Qubit_Werner_Sta.pdf.pdf\"\n     onclick=\"log_download('zhang-chitambar-exactsteeringboundfortwoqubitwernerstates-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/34968950-2132-0545-73a7-c55ab0bcae63/Chitambar_2024_Exact_Steering_Bound_for_Two_Qubit_Werner_Sta.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Exact Steering Bound for Two-Qubit Werner States [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.132.250201\"\n     onclick=\"log_download('zhang-chitambar-exactsteeringboundfortwoqubitwernerstates-2024', 'http://doi.org/10.1103/PhysRevLett.132.250201', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/zhang-chitambar-exactsteeringboundfortwoqubitwernerstates-2024\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('zhang-chitambar-exactsteeringboundfortwoqubitwernerstates-2024')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Exact Steering Bound for Two-Qubit Werner States},\n type = {article},\n year = {2024},\n volume = {132},\n month = {6},\n publisher = {American Physical Society},\n day = {21},\n id = {0385ce87-2776-3d90-9d47-b102269cdc3c},\n created = {2025-04-11T23:19:47.397Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-11T23:20:53.166Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Whether positive operator-valued measures (POVMs) provide advantages in demonstrating Bell nonlocality has remained unknown, even in the simple scenario of Einstein-Podolsky-Rosen steering with noisy singlet state, known as Werner states. Here we resolve this long-standing open problem by constructing a local hidden state model for Werner states with any visibility r≤1/2 under general POVMs, thereby closing the so-called Werner gap. This construction is based on an exact measurement compatibility model for the set of all noisy POVMs and also provides a local hidden variable model for a larger range of Werner states than previously known.},\n bibtype = {article},\n author = {Zhang, Yujie and Chitambar, Eric},\n doi = {10.1103/PhysRevLett.132.250201},\n journal = {Physical Review Letters},\n number = {25}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Whether positive operator-valued measures (POVMs) provide advantages in demonstrating Bell nonlocality has remained unknown, even in the simple scenario of Einstein-Podolsky-Rosen steering with noisy singlet state, known as Werner states. Here we resolve this long-standing open problem by constructing a local hidden state model for Werner states with any visibility r≤1/2 under general POVMs, thereby closing the so-called Werner gap. This construction is based on an exact measurement compatibility model for the set of all noisy POVMs and also provides a local hidden variable model for a larger range of Werner states than previously known.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"nayak-chitambar-varshney-reliablequantummemorieswithunreliablecomponents-2024\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/26c9a6a9-600d-1f67-5f6f-238813ccaf8f/Varshney_2024_Reliable_quantum_memories_with_unreliable_comp.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'nayak-chitambar-varshney-reliablequantummemorieswithunreliablecomponents-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/26c9a6a9-600d-1f67-5f6f-238813ccaf8f/Varshney_2024_Reliable_quantum_memories_with_unreliable_comp.pdf.pdf', event);\">\n    Reliable quantum memories with unreliable components.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Nayak,  A., K.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Varshney,  L., R.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 110(3): 032423. 9 2024.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/26c9a6a9-600d-1f67-5f6f-238813ccaf8f/Varshney_2024_Reliable_quantum_memories_with_unreliable_comp.pdf.pdf\"\n     onclick=\"log_download('nayak-chitambar-varshney-reliablequantummemorieswithunreliablecomponents-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/26c9a6a9-600d-1f67-5f6f-238813ccaf8f/Varshney_2024_Reliable_quantum_memories_with_unreliable_comp.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Reliable quantum memories with unreliable components [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n  <a href=\"https://link.aps.org/doi/10.1103/PhysRevA.110.032423\"\n     onclick=\"log_download('nayak-chitambar-varshney-reliablequantummemorieswithunreliablecomponents-2024', 'https://link.aps.org/doi/10.1103/PhysRevA.110.032423', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/link.svg\"\n\t     alt=\"Reliable quantum memories with unreliable components [link]\"\n       title=\"Website\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Website</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.110.032423\"\n     onclick=\"log_download('nayak-chitambar-varshney-reliablequantummemorieswithunreliablecomponents-2024', 'http://doi.org/10.1103/PhysRevA.110.032423', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/nayak-chitambar-varshney-reliablequantummemorieswithunreliablecomponents-2024\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('nayak-chitambar-varshney-reliablequantummemorieswithunreliablecomponents-2024')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Reliable quantum memories with unreliable components},\n type = {article},\n year = {2024},\n pages = {032423},\n volume = {110},\n websites = {https://link.aps.org/doi/10.1103/PhysRevA.110.032423},\n month = {9},\n day = {18},\n id = {68d07fba-57ea-32d6-bb8d-94742cf3c7ed},\n created = {2025-04-11T23:19:47.953Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-11T23:20:50.118Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n bibtype = {article},\n author = {Nayak, Anuj K. and Chitambar, Eric and Varshney, Lav R.},\n doi = {10.1103/PhysRevA.110.032423},\n journal = {Physical Review A},\n number = {3}\n}</pre>\n</div>\n\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chen-zhang-winter-lorenz-chitambar-informationcarriedbyasingleparticleinquantummultipleaccesschannels-2024\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/723b9bc9-2565-2039-661b-5898662cb697/Chitambar_2024_Information_carried_by_a_single_particle_in_q.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'chen-zhang-winter-lorenz-chitambar-informationcarriedbyasingleparticleinquantummultipleaccesschannels-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/723b9bc9-2565-2039-661b-5898662cb697/Chitambar_2024_Information_carried_by_a_single_particle_in_q.pdf.pdf', event);\">\n    Information carried by a single particle in quantum multiple-access channels.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Chen,  X.; Zhang,  Y.; Winter,  A.; Lorenz,  V., O.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 109(6). 6 2024.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/723b9bc9-2565-2039-661b-5898662cb697/Chitambar_2024_Information_carried_by_a_single_particle_in_q.pdf.pdf\"\n     onclick=\"log_download('chen-zhang-winter-lorenz-chitambar-informationcarriedbyasingleparticleinquantummultipleaccesschannels-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/723b9bc9-2565-2039-661b-5898662cb697/Chitambar_2024_Information_carried_by_a_single_particle_in_q.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Information carried by a single particle in quantum multiple-access channels [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.109.062420\"\n     onclick=\"log_download('chen-zhang-winter-lorenz-chitambar-informationcarriedbyasingleparticleinquantummultipleaccesschannels-2024', 'http://doi.org/10.1103/PhysRevA.109.062420', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chen-zhang-winter-lorenz-chitambar-informationcarriedbyasingleparticleinquantummultipleaccesschannels-2024\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chen-zhang-winter-lorenz-chitambar-informationcarriedbyasingleparticleinquantummultipleaccesschannels-2024')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Information carried by a single particle in quantum multiple-access channels},\n type = {article},\n year = {2024},\n volume = {109},\n month = {6},\n publisher = {American Physical Society},\n day = {1},\n id = {50e5332f-f2ce-3875-9551-af5879f171fc},\n created = {2025-04-11T23:19:49.710Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-11T23:20:38.574Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Nonclassical features of quantum systems have the potential to strengthen the way we currently exchange information. In this paper, we explore this enhancement on the most basic level of single particles. To be more precise, we compare how well multiparty information can be transmitted to a single receiver using just one classical or quantum particle. Our approach is based on a multiple-access communication model in which messages can be encoded into a single particle that is coherently distributed across multiple spatial modes. Theoretically, we derive lower bounds on the accessible information in the quantum setting that strictly separate it from the classical scenario. This separation is found whenever there is more than one sender, and also when there is just a single sender who has a shared phase reference with the receiver. When there is only one sender, the separation is impossible without a shared phase reference due to the famous Holevo&#x27;s bound. Experimentally, we present a proof-of-principle demonstration of such quantum advantage in single-particle communication by implementing a multiport interferometer with messages being encoded along the different trajectories. Specifically, we consider a two-sender communication protocol built by a three-port optical interferometer. In this scenario, the rate sum achievable with a classical particle is upper bounded by one bit, while we experimentally observe a rate sum of 1.0152±0.0034 bits in the quantum setup.},\n bibtype = {article},\n author = {Chen, Xinan and Zhang, Yujie and Winter, Andreas and Lorenz, Virginia O. and Chitambar, Eric},\n doi = {10.1103/PhysRevA.109.062420},\n journal = {Physical Review A},\n number = {6}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Nonclassical features of quantum systems have the potential to strengthen the way we currently exchange information. In this paper, we explore this enhancement on the most basic level of single particles. To be more precise, we compare how well multiparty information can be transmitted to a single receiver using just one classical or quantum particle. Our approach is based on a multiple-access communication model in which messages can be encoded into a single particle that is coherently distributed across multiple spatial modes. Theoretically, we derive lower bounds on the accessible information in the quantum setting that strictly separate it from the classical scenario. This separation is found whenever there is more than one sender, and also when there is just a single sender who has a shared phase reference with the receiver. When there is only one sender, the separation is impossible without a shared phase reference due to the famous Holevo's bound. Experimentally, we present a proof-of-principle demonstration of such quantum advantage in single-particle communication by implementing a multiport interferometer with messages being encoded along the different trajectories. Specifically, we consider a two-sender communication protocol built by a three-port optical interferometer. In this scenario, the rate sum achievable with a classical particle is upper bounded by one bit, while we experimentally observe a rate sum of 1.0152±0.0034 bits in the quantum setup.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"george-chitambar-conerestrictedinformationtheory-2024\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/15f1a428-2836-242f-1ef6-c3d2739b8037/George_2024_Cone_restricted_information_theory.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'george-chitambar-conerestrictedinformationtheory-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/15f1a428-2836-242f-1ef6-c3d2739b8037/George_2024_Cone_restricted_information_theory.pdf.pdf', event);\">\n    Cone-restricted information theory.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  George,  I.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Journal of Physics A: Mathematical and Theoretical</i>, 57(26). 6 2024.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/15f1a428-2836-242f-1ef6-c3d2739b8037/George_2024_Cone_restricted_information_theory.pdf.pdf\"\n     onclick=\"log_download('george-chitambar-conerestrictedinformationtheory-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/15f1a428-2836-242f-1ef6-c3d2739b8037/George_2024_Cone_restricted_information_theory.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Cone-restricted information theory [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1088/1751-8121/ad52d5\"\n     onclick=\"log_download('george-chitambar-conerestrictedinformationtheory-2024', 'http://doi.org/10.1088/1751-8121/ad52d5', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/george-chitambar-conerestrictedinformationtheory-2024\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('george-chitambar-conerestrictedinformationtheory-2024')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Cone-restricted information theory},\n type = {article},\n year = {2024},\n keywords = {conic programming,convex geometry,quantum entropies,quantum information theory},\n volume = {57},\n month = {6},\n publisher = {Institute of Physics},\n day = {28},\n id = {c39258e0-d504-324c-8855-3f591d4dda3f},\n created = {2025-04-12T17:56:44.686Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T18:03:24.095Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {The max-relative entropy and the conditional min-entropy of a quantum state plays a central role in one-shot and zero-error quantum information theory. One attractive feature of this quantity is that it can be expressed as an optimization over the cone of positive semidefinite operators. Recently, it was shown that when replacing this cone with the cone of separable operators, a new type of conditional min-entropy emerges that admits an operational interpretation in terms of communicating classical information over a quantum channel. In this work, we explore more deeply the idea of building information-theoretic quantities from different base cones and determine which results in quantum information theory rely upon the positive semidefinite cone and which can be generalized. In terms of asymptotic information processing, we find that the standard equipartition properties break down if a given cone fails to approximate the positive semidefinite cone sufficiently well. We also show that the near-equivalence of the smooth max and Hartley entropies breaks down in this setting. We present parallel results for the extended conditional min-entropy, which requires extending the notion of k-superpositive channels to superchannels. On the other hand, we show that for classical-quantum states the separable cone is sufficient to re-cover the asymptotic theory, thereby drawing a strong distinction between the fully and partial quantum settings. We also present operational uses of this framework. We show that the cone restricted min-entropy of a Choi operator captures a measure of entanglement-assisted noiseless classical communication using restricted measurements. We also introduce a novel min-entropy-like quantity that captures the conditions for when one quantum channel can be transformed into another using bistochastic pre-processing. Lastly, we relate this framework to general conic norms and their non-additivity. Throughout this work, we concretely study generalized entropies in resource theories that capture locality and resource theories of coherence/Abelian symmetries.},\n bibtype = {article},\n author = {George, Ian and Chitambar, Eric},\n doi = {10.1088/1751-8121/ad52d5},\n journal = {Journal of Physics A: Mathematical and Theoretical},\n number = {26}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  The max-relative entropy and the conditional min-entropy of a quantum state plays a central role in one-shot and zero-error quantum information theory. One attractive feature of this quantity is that it can be expressed as an optimization over the cone of positive semidefinite operators. Recently, it was shown that when replacing this cone with the cone of separable operators, a new type of conditional min-entropy emerges that admits an operational interpretation in terms of communicating classical information over a quantum channel. In this work, we explore more deeply the idea of building information-theoretic quantities from different base cones and determine which results in quantum information theory rely upon the positive semidefinite cone and which can be generalized. In terms of asymptotic information processing, we find that the standard equipartition properties break down if a given cone fails to approximate the positive semidefinite cone sufficiently well. We also show that the near-equivalence of the smooth max and Hartley entropies breaks down in this setting. We present parallel results for the extended conditional min-entropy, which requires extending the notion of k-superpositive channels to superchannels. On the other hand, we show that for classical-quantum states the separable cone is sufficient to re-cover the asymptotic theory, thereby drawing a strong distinction between the fully and partial quantum settings. We also present operational uses of this framework. We show that the cone restricted min-entropy of a Choi operator captures a measure of entanglement-assisted noiseless classical communication using restricted measurements. We also introduce a novel min-entropy-like quantity that captures the conditions for when one quantum channel can be transformed into another using bistochastic pre-processing. Lastly, we relate this framework to general conic norms and their non-additivity. Throughout this work, we concretely study generalized entropies in resource theories that capture locality and resource theories of coherence/Abelian symmetries.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"schatzki-liu-cerezo-chitambar-hierarchyofmultipartitecorrelationsbasedonconcentratableentanglement-2024\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4e022833-6a0e-f161-59cc-919b761c4517/Schatzki_2024_Hierarchy_of_multipartite_correlations_based_o.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'schatzki-liu-cerezo-chitambar-hierarchyofmultipartitecorrelationsbasedonconcentratableentanglement-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4e022833-6a0e-f161-59cc-919b761c4517/Schatzki_2024_Hierarchy_of_multipartite_correlations_based_o.pdf.pdf', event);\">\n    Hierarchy of multipartite correlations based on concentratable entanglement.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Schatzki,  L.; Liu,  G.; Cerezo,  M.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Research</i>, 6(2). 4 2024.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4e022833-6a0e-f161-59cc-919b761c4517/Schatzki_2024_Hierarchy_of_multipartite_correlations_based_o.pdf.pdf\"\n     onclick=\"log_download('schatzki-liu-cerezo-chitambar-hierarchyofmultipartitecorrelationsbasedonconcentratableentanglement-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4e022833-6a0e-f161-59cc-919b761c4517/Schatzki_2024_Hierarchy_of_multipartite_correlations_based_o.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Hierarchy of multipartite correlations based on concentratable entanglement [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevResearch.6.023019\"\n     onclick=\"log_download('schatzki-liu-cerezo-chitambar-hierarchyofmultipartitecorrelationsbasedonconcentratableentanglement-2024', 'http://doi.org/10.1103/PhysRevResearch.6.023019', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/schatzki-liu-cerezo-chitambar-hierarchyofmultipartitecorrelationsbasedonconcentratableentanglement-2024\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('schatzki-liu-cerezo-chitambar-hierarchyofmultipartitecorrelationsbasedonconcentratableentanglement-2024')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Hierarchy of multipartite correlations based on concentratable entanglement},\n type = {article},\n year = {2024},\n volume = {6},\n month = {4},\n publisher = {American Physical Society},\n day = {1},\n id = {0655f4a8-c093-34eb-84d3-c3c8da4331f4},\n created = {2025-04-12T18:01:06.082Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T18:03:26.987Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Multipartite entanglement is one of the hallmarks of quantum mechanics and is central to quantum information processing. In this work we show that concentratable entanglement (CE), an operationally motivated entanglement measure, induces a hierarchy upon pure states from which different entanglement structures can be experimentally certified. In particular, we find that nearly all genuine multipartite entangled states can be verified through the CE. Interestingly, GHZ states prove to be far from maximally entangled according to this measure. Instead we find the exact maximal value and corresponding states for up to 18 qubits and show that these correspond to extremal quantum error correcting codes. The latter allows us to unravel a deep connection between CE and coding theory. Finally, our results also offer an alternative proof, on up to 31 qubits, that absolutely maximally entangled states do not exist.},\n bibtype = {article},\n author = {Schatzki, Louis and Liu, Guangkuo and Cerezo, M. and Chitambar, Eric},\n doi = {10.1103/PhysRevResearch.6.023019},\n journal = {Physical Review Research},\n number = {2}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Multipartite entanglement is one of the hallmarks of quantum mechanics and is central to quantum information processing. In this work we show that concentratable entanglement (CE), an operationally motivated entanglement measure, induces a hierarchy upon pure states from which different entanglement structures can be experimentally certified. In particular, we find that nearly all genuine multipartite entangled states can be verified through the CE. Interestingly, GHZ states prove to be far from maximally entangled according to this measure. Instead we find the exact maximal value and corresponding states for up to 18 qubits and show that these correspond to extremal quantum error correcting codes. The latter allows us to unravel a deep connection between CE and coding theory. Finally, our results also offer an alternative proof, on up to 31 qubits, that absolutely maximally entangled states do not exist.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"ji-chitambar-incompatibilityasaresourceforprogrammablequantuminstruments-2024\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/20523456-3cc7-8b57-315b-4df63c3c476f/Ji_2024_Incompatibility_as_a_Resource_for_Programmable_Quant.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'ji-chitambar-incompatibilityasaresourceforprogrammablequantuminstruments-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/20523456-3cc7-8b57-315b-4df63c3c476f/Ji_2024_Incompatibility_as_a_Resource_for_Programmable_Quant.pdf.pdf', event);\">\n    Incompatibility as a Resource for Programmable Quantum Instruments.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Ji,  K.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>PRX Quantum</i>, 5(1). 1 2024.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/20523456-3cc7-8b57-315b-4df63c3c476f/Ji_2024_Incompatibility_as_a_Resource_for_Programmable_Quant.pdf.pdf\"\n     onclick=\"log_download('ji-chitambar-incompatibilityasaresourceforprogrammablequantuminstruments-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/20523456-3cc7-8b57-315b-4df63c3c476f/Ji_2024_Incompatibility_as_a_Resource_for_Programmable_Quant.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Incompatibility as a Resource for Programmable Quantum Instruments [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PRXQuantum.5.010340\"\n     onclick=\"log_download('ji-chitambar-incompatibilityasaresourceforprogrammablequantuminstruments-2024', 'http://doi.org/10.1103/PRXQuantum.5.010340', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/ji-chitambar-incompatibilityasaresourceforprogrammablequantuminstruments-2024\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('ji-chitambar-incompatibilityasaresourceforprogrammablequantuminstruments-2024')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Incompatibility as a Resource for Programmable Quantum Instruments},\n type = {article},\n year = {2024},\n volume = {5},\n month = {1},\n publisher = {American Physical Society},\n day = {1},\n id = {37d28aa7-b884-3fd7-b908-383e76f00f66},\n created = {2025-04-12T18:01:07.654Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T18:03:30.443Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Quantum instruments represent the most general type of quantum measurement, as they incorporate processes with both classical and quantum outputs. In many scenarios, it may be desirable to have some &quot;on-demand&quot;device that is capable of implementing one of many possible instruments whenever the experimenter desires. We refer to such objects as programmable instrument devices (PIDs), and this paper studies PIDs from a resource-theoretic perspective. A physically important class of PIDs are those that do not require quantum memories to implement, and these are naturally &quot;free&quot;in this resource theory. Additionally, these free objects correspond precisely to the class of unsteerable channel assemblages in the study of channel steering. The traditional notion of measurement incompatibility emerges as a resource in this theory since any PID controlling an incompatible family of instruments requires a quantum memory to build. We identify an incompatibility preorder between PIDs based on whether one can be transformed into another using processes that do not require additional quantum memories. Necessary and sufficient conditions are derived for when such transformations are possible based on how well certain guessing games can be played using a given PID. Ultimately our results provide an operational characterization of incompatibility, and they offer semi-device-independent tests for incompatibility in the most general types of quantum instruments.},\n bibtype = {article},\n author = {Ji, Kaiyuan and Chitambar, Eric},\n doi = {10.1103/PRXQuantum.5.010340},\n journal = {PRX Quantum},\n number = {1}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Quantum instruments represent the most general type of quantum measurement, as they incorporate processes with both classical and quantum outputs. In many scenarios, it may be desirable to have some \"on-demand\"device that is capable of implementing one of many possible instruments whenever the experimenter desires. We refer to such objects as programmable instrument devices (PIDs), and this paper studies PIDs from a resource-theoretic perspective. A physically important class of PIDs are those that do not require quantum memories to implement, and these are naturally \"free\"in this resource theory. Additionally, these free objects correspond precisely to the class of unsteerable channel assemblages in the study of channel steering. The traditional notion of measurement incompatibility emerges as a resource in this theory since any PID controlling an incompatible family of instruments requires a quantum memory to build. We identify an incompatibility preorder between PIDs based on whether one can be transformed into another using processes that do not require additional quantum memories. Necessary and sufficient conditions are derived for when such transformations are possible based on how well certain guessing games can be played using a given PID. Ultimately our results provide an operational characterization of incompatibility, and they offer semi-device-independent tests for incompatibility in the most general types of quantum instruments.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"schatzki-ma-solomonik-chitambar-tensorrankandothermultipartiteentanglementmeasuresofgraphstates-2024\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/527b3d70-9a90-75ef-56ba-4f27f2b7cc97/Schatzki_2024_Tensor_rank_and_other_multipartite_entanglemen.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'schatzki-ma-solomonik-chitambar-tensorrankandothermultipartiteentanglementmeasuresofgraphstates-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/527b3d70-9a90-75ef-56ba-4f27f2b7cc97/Schatzki_2024_Tensor_rank_and_other_multipartite_entanglemen.pdf.pdf', event);\">\n    Tensor rank and other multipartite entanglement measures of graph states.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Schatzki,  L.; Ma,  L.; Solomonik,  E.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 110(3). 9 2024.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/527b3d70-9a90-75ef-56ba-4f27f2b7cc97/Schatzki_2024_Tensor_rank_and_other_multipartite_entanglemen.pdf.pdf\"\n     onclick=\"log_download('schatzki-ma-solomonik-chitambar-tensorrankandothermultipartiteentanglementmeasuresofgraphstates-2024', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/527b3d70-9a90-75ef-56ba-4f27f2b7cc97/Schatzki_2024_Tensor_rank_and_other_multipartite_entanglemen.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Tensor rank and other multipartite entanglement measures of graph states [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.110.032409\"\n     onclick=\"log_download('schatzki-ma-solomonik-chitambar-tensorrankandothermultipartiteentanglementmeasuresofgraphstates-2024', 'http://doi.org/10.1103/PhysRevA.110.032409', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/schatzki-ma-solomonik-chitambar-tensorrankandothermultipartiteentanglementmeasuresofgraphstates-2024\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('schatzki-ma-solomonik-chitambar-tensorrankandothermultipartiteentanglementmeasuresofgraphstates-2024')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Tensor rank and other multipartite entanglement measures of graph states},\n type = {article},\n year = {2024},\n volume = {110},\n month = {9},\n publisher = {American Physical Society},\n day = {1},\n id = {d0f4460c-c596-3010-a7e0-e5cf875cebc3},\n created = {2025-04-13T16:59:49.510Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-13T16:59:58.743Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Graph states play an important role in quantum information theory through their connection to measurement-based computing and error correction. Prior work revealed elegant connections between the graph structure of these states and their multipartite entanglement. We continue this line of investigation by identifying additional entanglement properties for certain types of graph states. From the perspective of tensor theory, we tighten both upper and lower bounds on the tensor rank of odd ring states (|R2n+1)) to read 2n+1≤rank(|R2n+1))≤3×2n-1. Next we show that several multipartite extensions of bipartite entanglement measures are dichotomous for graph states based on the connectivity of the corresponding graph. Finally, we give a simple graph rule for computing the n-tangle τn.},\n bibtype = {article},\n author = {Schatzki, Louis and Ma, Linjian and Solomonik, Edgar and Chitambar, Eric},\n doi = {10.1103/PhysRevA.110.032409},\n journal = {Physical Review A},\n number = {3}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Graph states play an important role in quantum information theory through their connection to measurement-based computing and error correction. Prior work revealed elegant connections between the graph structure of these states and their multipartite entanglement. We continue this line of investigation by identifying additional entanglement properties for certain types of graph states. From the perspective of tensor theory, we tighten both upper and lower bounds on the tensor rank of odd ring states (|R2n+1)) to read 2n+1≤rank(|R2n+1))≤3×2n-1. Next we show that several multipartite extensions of bipartite entanglement measures are dichotomous for graph states based on the connectivity of the corresponding graph. Finally, we give a simple graph rule for computing the n-tangle τn.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2023\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2023')\"\n      onkeypress=\"toggleGroup('group_2023')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2023</span>\n      <span class=\"bibbase_group_count\">\n        \n        (6)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"chitambar-george-doolittle-junge-thecommunicationvalueofaquantumchannel-2023\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4ee75966-1617-78b7-6791-3e955f33b61b/Chitambar_2023_The_Communication_Value_of_a_Quantum_Channel.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'chitambar-george-doolittle-junge-thecommunicationvalueofaquantumchannel-2023', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4ee75966-1617-78b7-6791-3e955f33b61b/Chitambar_2023_The_Communication_Value_of_a_Quantum_Channel.pdf.pdf', event);\">\n    The Communication Value of a Quantum Channel.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; George,  I.; Doolittle,  B.;  and Junge,  M.\n</span>\n\n  \n\n</span>\n\n  In <i>IEEE Transactions on Information Theory</i>, volume 69, pages 1660-1679, 3 2023. Institute of Electrical and Electronics Engineers Inc.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4ee75966-1617-78b7-6791-3e955f33b61b/Chitambar_2023_The_Communication_Value_of_a_Quantum_Channel.pdf.pdf\"\n     onclick=\"log_download('chitambar-george-doolittle-junge-thecommunicationvalueofaquantumchannel-2023', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4ee75966-1617-78b7-6791-3e955f33b61b/Chitambar_2023_The_Communication_Value_of_a_Quantum_Channel.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"The Communication Value of a Quantum Channel [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1109/TIT.2022.3218540\"\n     onclick=\"log_download('chitambar-george-doolittle-junge-thecommunicationvalueofaquantumchannel-2023', 'http://doi.org/10.1109/TIT.2022.3218540', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-george-doolittle-junge-thecommunicationvalueofaquantumchannel-2023\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-george-doolittle-junge-thecommunicationvalueofaquantumchannel-2023')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@inproceedings{\n title = {The Communication Value of a Quantum Channel},\n type = {inproceedings},\n year = {2023},\n keywords = {Quantum information science,quantum channels,quantum entanglement},\n pages = {1660-1679},\n volume = {69},\n issue = {3},\n month = {3},\n publisher = {Institute of Electrical and Electronics Engineers Inc.},\n day = {1},\n id = {dae6743e-b456-39b8-99d3-ce430ef1797a},\n created = {2025-04-11T19:50:02.576Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-11T19:50:57.786Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {There are various ways to quantify the communication capabilities of a quantum channel. In this work we introduce the communication value (cv) of quantum channel, which describes the optimal probability of guessing the channel input from its output. By connecting to prior work on zero-error channel simulation, we show that the cv and its entanglement-assisted variant also offer dual interpretations as the classical communication cost for perfectly simulating different aspects of a channel using non-signaling resources. Our study involves characterizing the communication value as a generalized conditional min-entropy over the cone of separable operators. Using this characterization, we evaluate the cv for all qubit channels and higher-dimensional channels with certain symmetries. We find that the any entanglement-breaking channel has multiplicative cv when used in parallel with any other channel; the same is shown to hold for Pauli channels and partially depolarizing channels. In contrast, the cv is found to be non-multiplicative for a subset of the well-known Werner-Holevo channels. A final component of this work investigates relaxations of the channel cv to other cones such as the set of operators having a positive partial transpose (PPT).},\n bibtype = {inproceedings},\n author = {Chitambar, Eric and George, Ian and Doolittle, Brian and Junge, Marius},\n doi = {10.1109/TIT.2022.3218540},\n booktitle = {IEEE Transactions on Information Theory}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  There are various ways to quantify the communication capabilities of a quantum channel. In this work we introduce the communication value (cv) of quantum channel, which describes the optimal probability of guessing the channel input from its output. By connecting to prior work on zero-error channel simulation, we show that the cv and its entanglement-assisted variant also offer dual interpretations as the classical communication cost for perfectly simulating different aspects of a channel using non-signaling resources. Our study involves characterizing the communication value as a generalized conditional min-entropy over the cone of separable operators. Using this characterization, we evaluate the cv for all qubit channels and higher-dimensional channels with certain symmetries. We find that the any entanglement-breaking channel has multiplicative cv when used in parallel with any other channel; the same is shown to hold for Pauli channels and partially depolarizing channels. In contrast, the cv is found to be non-multiplicative for a subset of the well-known Werner-Holevo channels. A final component of this work investigates relaxations of the channel cv to other cones such as the set of operators having a positive partial transpose (PPT).\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"gattolamas-chitambar-multipartitenonlocalityincliffordnetworks-2023\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/16d6853b-76ac-6373-1c19-08ffea9cac0b/Chitambar_2023_Multipartite_Nonlocality_in_Clifford_Networks.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'gattolamas-chitambar-multipartitenonlocalityincliffordnetworks-2023', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/16d6853b-76ac-6373-1c19-08ffea9cac0b/Chitambar_2023_Multipartite_Nonlocality_in_Clifford_Networks.pdf.pdf', event);\">\n    Multipartite Nonlocality in Clifford Networks.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Gatto Lamas,  A.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 130(24). 6 2023.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/16d6853b-76ac-6373-1c19-08ffea9cac0b/Chitambar_2023_Multipartite_Nonlocality_in_Clifford_Networks.pdf.pdf\"\n     onclick=\"log_download('gattolamas-chitambar-multipartitenonlocalityincliffordnetworks-2023', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/16d6853b-76ac-6373-1c19-08ffea9cac0b/Chitambar_2023_Multipartite_Nonlocality_in_Clifford_Networks.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Multipartite Nonlocality in Clifford Networks [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.130.240802\"\n     onclick=\"log_download('gattolamas-chitambar-multipartitenonlocalityincliffordnetworks-2023', 'http://doi.org/10.1103/PhysRevLett.130.240802', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/gattolamas-chitambar-multipartitenonlocalityincliffordnetworks-2023\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('gattolamas-chitambar-multipartitenonlocalityincliffordnetworks-2023')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Multipartite Nonlocality in Clifford Networks},\n type = {article},\n year = {2023},\n volume = {130},\n month = {6},\n publisher = {American Physical Society},\n day = {16},\n id = {2cdf606b-7faa-3797-8a01-c41dde4a4f53},\n created = {2025-04-11T23:19:47.123Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T17:35:10.944Z},\n read = {true},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {We adopt a resource-theoretic framework to classify different types of quantum network nonlocality in terms of operational constraints placed on the network. One type of constraint limits the parties to perform local Clifford gates on pure stabilizer states, and we show that quantum network nonlocality cannot emerge in this setting. Yet, if the constraint is relaxed to allow for mixed stabilizer states, then network nonlocality can indeed be obtained. We additionally show that bipartite entanglement is sufficient for generating all forms of quantum network nonlocality when allowing for postselection, a property analogous to the universality of bipartite entanglement for generating all forms of multipartite entangled states.},\n bibtype = {article},\n author = {Gatto Lamas, Amanda and Chitambar, Eric},\n doi = {10.1103/PhysRevLett.130.240802},\n journal = {Physical Review Letters},\n number = {24}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  We adopt a resource-theoretic framework to classify different types of quantum network nonlocality in terms of operational constraints placed on the network. One type of constraint limits the parties to perform local Clifford gates on pure stabilizer states, and we show that quantum network nonlocality cannot emerge in this setting. Yet, if the constraint is relaxed to allow for mixed stabilizer states, then network nonlocality can indeed be obtained. We additionally show that bipartite entanglement is sufficient for generating all forms of quantum network nonlocality when allowing for postselection, a property analogous to the universality of bipartite entanglement for generating all forms of multipartite entangled states.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"doolittle-bromley-killoran-chitambar-variationalquantumoptimizationofnonlocalityinnoisyquantumnetworks-2023\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7d02becd-af4d-2057-0e8c-9c3da00cb43f/Chitambar_2023_Variational_Quantum_Optimization_of_Nonlocali.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'doolittle-bromley-killoran-chitambar-variationalquantumoptimizationofnonlocalityinnoisyquantumnetworks-2023', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7d02becd-af4d-2057-0e8c-9c3da00cb43f/Chitambar_2023_Variational_Quantum_Optimization_of_Nonlocali.pdf.pdf', event);\">\n    Variational Quantum Optimization of Nonlocality in Noisy Quantum Networks.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Doolittle,  B.; Bromley,  R., T.; Killoran,  N.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>IEEE Transactions on Quantum Engineering</i>, 4.  2023.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7d02becd-af4d-2057-0e8c-9c3da00cb43f/Chitambar_2023_Variational_Quantum_Optimization_of_Nonlocali.pdf.pdf\"\n     onclick=\"log_download('doolittle-bromley-killoran-chitambar-variationalquantumoptimizationofnonlocalityinnoisyquantumnetworks-2023', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7d02becd-af4d-2057-0e8c-9c3da00cb43f/Chitambar_2023_Variational_Quantum_Optimization_of_Nonlocali.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Variational Quantum Optimization of Nonlocality in Noisy Quantum Networks [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1109/TQE.2023.3243849\"\n     onclick=\"log_download('doolittle-bromley-killoran-chitambar-variationalquantumoptimizationofnonlocalityinnoisyquantumnetworks-2023', 'http://doi.org/10.1109/TQE.2023.3243849', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/doolittle-bromley-killoran-chitambar-variationalquantumoptimizationofnonlocalityinnoisyquantumnetworks-2023\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('doolittle-bromley-killoran-chitambar-variationalquantumoptimizationofnonlocalityinnoisyquantumnetworks-2023')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Variational Quantum Optimization of Nonlocality in Noisy Quantum Networks},\n type = {article},\n year = {2023},\n keywords = {Design and simulation tools,noisy intermediate-scale quantum (NISQ) algorithms and devices,quantum networking},\n volume = {4},\n publisher = {Institute of Electrical and Electronics Engineers Inc.},\n id = {f48dc44d-f1ae-3347-a029-cdc9bdd476f5},\n created = {2025-04-11T23:19:49.242Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-11T23:20:42.332Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {The noise and complexity inherent to quantum communication networks leads to technical challenges in designing quantum network protocols using classical methods. We address this issue with a hybrid variational quantum optimization (VQO) framework that simulates quantum networks on quantum hardware and optimizes the simulation using differential programming. We maximize nonlocality in noisy quantum networks to showcase our VQO framework. Using a classical simulator, we investigate the noise robustness of quantum nonlocality. Our VQO methods reproduce known results and uncover novel phenomena. We find that maximally entangled states maximize nonlocality in the presence of unital qubit channels, while nonmaximally entangled states can maximize nonlocality in the presence of nonunital qubit channels. Thus, we show VQO to be a practical design tool for quantum networks even when run on a classical simulator. Finally, using IBM quantum computers, we demonstrate that our VQO framework can maximize nonlocality on noisy quantum hardware. In the long term, our VQO techniques show promise of scaling beyond classical approaches and can be deployed on quantum network hardware to optimize network protocols against their inherent noise.},\n bibtype = {article},\n author = {Doolittle, Brian and Bromley, R. Thomas and Killoran, Nathan and Chitambar, Eric},\n doi = {10.1109/TQE.2023.3243849},\n journal = {IEEE Transactions on Quantum Engineering}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  The noise and complexity inherent to quantum communication networks leads to technical challenges in designing quantum network protocols using classical methods. We address this issue with a hybrid variational quantum optimization (VQO) framework that simulates quantum networks on quantum hardware and optimizes the simulation using differential programming. We maximize nonlocality in noisy quantum networks to showcase our VQO framework. Using a classical simulator, we investigate the noise robustness of quantum nonlocality. Our VQO methods reproduce known results and uncover novel phenomena. We find that maximally entangled states maximize nonlocality in the presence of unital qubit channels, while nonmaximally entangled states can maximize nonlocality in the presence of nonunital qubit channels. Thus, we show VQO to be a practical design tool for quantum networks even when run on a classical simulator. Finally, using IBM quantum computers, we demonstrate that our VQO framework can maximize nonlocality on noisy quantum hardware. In the long term, our VQO techniques show promise of scaling beyond classical approaches and can be deployed on quantum network hardware to optimize network protocols against their inherent noise.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chen-doolittle-larson-saleem-chitambar-inferringquantumnetworktopologyusinglocalmeasurements-2023\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/638d802e-43c2-3359-1538-d14df26cbb47/Chitambar_2023_Inferring_Quantum_Network_Topology_Using_Loca.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'chen-doolittle-larson-saleem-chitambar-inferringquantumnetworktopologyusinglocalmeasurements-2023', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/638d802e-43c2-3359-1538-d14df26cbb47/Chitambar_2023_Inferring_Quantum_Network_Topology_Using_Loca.pdf.pdf', event);\">\n    Inferring Quantum Network Topology Using Local Measurements.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Chen,  D., T.; Doolittle,  B.; Larson,  J.; Saleem,  Z., H.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>PRX Quantum</i>, 4(4). 10 2023.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/638d802e-43c2-3359-1538-d14df26cbb47/Chitambar_2023_Inferring_Quantum_Network_Topology_Using_Loca.pdf.pdf\"\n     onclick=\"log_download('chen-doolittle-larson-saleem-chitambar-inferringquantumnetworktopologyusinglocalmeasurements-2023', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/638d802e-43c2-3359-1538-d14df26cbb47/Chitambar_2023_Inferring_Quantum_Network_Topology_Using_Loca.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Inferring Quantum Network Topology Using Local Measurements [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PRXQuantum.4.040347\"\n     onclick=\"log_download('chen-doolittle-larson-saleem-chitambar-inferringquantumnetworktopologyusinglocalmeasurements-2023', 'http://doi.org/10.1103/PRXQuantum.4.040347', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chen-doolittle-larson-saleem-chitambar-inferringquantumnetworktopologyusinglocalmeasurements-2023\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chen-doolittle-larson-saleem-chitambar-inferringquantumnetworktopologyusinglocalmeasurements-2023')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Inferring Quantum Network Topology Using Local Measurements},\n type = {article},\n year = {2023},\n volume = {4},\n month = {10},\n publisher = {American Physical Society},\n day = {1},\n id = {c5331bbe-92af-3034-851f-00d0f36141f2},\n created = {2025-04-11T23:19:51.710Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-11T23:20:33.438Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Statistical correlations that can be generated across the nodes in a quantum network depend crucially on its topology. However, this topological information might not be known a priori, or it may need to be verified. In this paper, we propose an efficient protocol for distinguishing and inferring the topology of a quantum network. We leverage entropic quantities - namely, the von Neumann entropy and the measured mutual information - as well as measurement covariance to uniquely characterize the topology. We show that the entropic quantities are sufficient to distinguish two networks that prepare GHZ states. Moreover, if qubit measurements are available, both entropic quantities and covariance can be used to infer the network topology without state-preparation assumptions. We show that the protocol can be entirely robust to noise and can be implemented via quantum variational optimization. Numerical experiments on both classical simulators and quantum hardware show that covariance is generally more reliable for accurately and efficiently inferring the topology, whereas entropy-based methods are often better at identifying the absence of entanglement in the low-shot regime.},\n bibtype = {article},\n author = {Chen, Daniel T. and Doolittle, Brian and Larson, Jeffrey and Saleem, Zain H. and Chitambar, Eric},\n doi = {10.1103/PRXQuantum.4.040347},\n journal = {PRX Quantum},\n number = {4}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Statistical correlations that can be generated across the nodes in a quantum network depend crucially on its topology. However, this topological information might not be known a priori, or it may need to be verified. In this paper, we propose an efficient protocol for distinguishing and inferring the topology of a quantum network. We leverage entropic quantities - namely, the von Neumann entropy and the measured mutual information - as well as measurement covariance to uniquely characterize the topology. We show that the entropic quantities are sufficient to distinguish two networks that prepare GHZ states. Moreover, if qubit measurements are available, both entropic quantities and covariance can be used to infer the network topology without state-preparation assumptions. We show that the protocol can be entirely robust to noise and can be implemented via quantum variational optimization. Numerical experiments on both classical simulators and quantum hardware show that covariance is generally more reliable for accurately and efficiently inferring the topology, whereas entropy-based methods are often better at identifying the absence of entanglement in the low-shot regime.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"doolittle-chitambar-maximalqubitviolationsofnlocalityinstarandchainnetworks-2023\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4eb2aa2c-e91d-2009-2c83-3094be2b7803/Doolittle_2023_Maximal_qubit_violations_of_n_locality_in_sta.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'doolittle-chitambar-maximalqubitviolationsofnlocalityinstarandchainnetworks-2023', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4eb2aa2c-e91d-2009-2c83-3094be2b7803/Doolittle_2023_Maximal_qubit_violations_of_n_locality_in_sta.pdf.pdf', event);\">\n    Maximal qubit violations of n -locality in star and chain networks.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Doolittle,  B.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 108(4). 10 2023.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4eb2aa2c-e91d-2009-2c83-3094be2b7803/Doolittle_2023_Maximal_qubit_violations_of_n_locality_in_sta.pdf.pdf\"\n     onclick=\"log_download('doolittle-chitambar-maximalqubitviolationsofnlocalityinstarandchainnetworks-2023', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/4eb2aa2c-e91d-2009-2c83-3094be2b7803/Doolittle_2023_Maximal_qubit_violations_of_n_locality_in_sta.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Maximal qubit violations of n -locality in star and chain networks [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.108.042409\"\n     onclick=\"log_download('doolittle-chitambar-maximalqubitviolationsofnlocalityinstarandchainnetworks-2023', 'http://doi.org/10.1103/PhysRevA.108.042409', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/doolittle-chitambar-maximalqubitviolationsofnlocalityinstarandchainnetworks-2023\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('doolittle-chitambar-maximalqubitviolationsofnlocalityinstarandchainnetworks-2023')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Maximal qubit violations of n -locality in star and chain networks},\n type = {article},\n year = {2023},\n volume = {108},\n month = {10},\n publisher = {American Physical Society},\n day = {1},\n id = {1154cbff-cca3-3080-bdaf-8c4a7a9538c2},\n created = {2025-04-12T17:56:25.189Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T18:03:57.166Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {The nonlocal correlations of noisy quantum systems are important for both understanding nature and developing quantum technology. We consider the correlations of star and chain quantum networks in which noisy entanglement sources are measured by nonsignaling parties. We derive the necessary and sufficient conditions for when a broad family of star and chain n-locality inequalities achieve their maximal quantum violation assuming that each party&#x27;s dichotomic observables are separable across qudit systems. When pairs of local dichotomic observables are considered on qubit systems, we derive maximal n-local violations that are larger and more robust to noise than the maximal n-locality violations reported previously. To obtain these larger values, we consider observables that we have not found in previous studies. Thus, we gain insights into self-testing entanglement sources and measurements in star and chain networks.},\n bibtype = {article},\n author = {Doolittle, Brian and Chitambar, Eric},\n doi = {10.1103/PhysRevA.108.042409},\n journal = {Physical Review A},\n number = {4}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  The nonlocal correlations of noisy quantum systems are important for both understanding nature and developing quantum technology. We consider the correlations of star and chain quantum networks in which noisy entanglement sources are measured by nonsignaling parties. We derive the necessary and sufficient conditions for when a broad family of star and chain n-locality inequalities achieve their maximal quantum violation assuming that each party's dichotomic observables are separable across qudit systems. When pairs of local dichotomic observables are considered on qubit systems, we derive maximal n-local violations that are larger and more robust to noise than the maximal n-locality violations reported previously. To obtain these larger values, we consider observables that we have not found in previous studies. Thus, we gain insights into self-testing entanglement sources and measurements in star and chain networks.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"liu-george-chitambar-theroundcomplexityoflocaloperationsandclassicalcommunicationloccinrandompartyentanglementdistillation-2023\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/07e6c3ed-8036-f62f-74b1-687e656c4af3/Liu_2023_The_Round_Complexity_of_Local_Operations_and_Classi.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'liu-george-chitambar-theroundcomplexityoflocaloperationsandclassicalcommunicationloccinrandompartyentanglementdistillation-2023', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/07e6c3ed-8036-f62f-74b1-687e656c4af3/Liu_2023_The_Round_Complexity_of_Local_Operations_and_Classi.pdf.pdf', event);\">\n    The Round Complexity of Local Operations and Classical Communication (LOCC) in Random-Party Entanglement Distillation.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Liu,  G.; George,  I.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Quantum</i>, 7.  2023.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/07e6c3ed-8036-f62f-74b1-687e656c4af3/Liu_2023_The_Round_Complexity_of_Local_Operations_and_Classi.pdf.pdf\"\n     onclick=\"log_download('liu-george-chitambar-theroundcomplexityoflocaloperationsandclassicalcommunicationloccinrandompartyentanglementdistillation-2023', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/07e6c3ed-8036-f62f-74b1-687e656c4af3/Liu_2023_The_Round_Complexity_of_Local_Operations_and_Classi.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"The Round Complexity of Local Operations and Classical Communication (LOCC) in Random-Party Entanglement Distillation [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.22331/Q-2023-09-07-1104\"\n     onclick=\"log_download('liu-george-chitambar-theroundcomplexityoflocaloperationsandclassicalcommunicationloccinrandompartyentanglementdistillation-2023', 'http://doi.org/10.22331/Q-2023-09-07-1104', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/liu-george-chitambar-theroundcomplexityoflocaloperationsandclassicalcommunicationloccinrandompartyentanglementdistillation-2023\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('liu-george-chitambar-theroundcomplexityoflocaloperationsandclassicalcommunicationloccinrandompartyentanglementdistillation-2023')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {The Round Complexity of Local Operations and Classical Communication (LOCC) in Random-Party Entanglement Distillation},\n type = {article},\n year = {2023},\n volume = {7},\n publisher = {Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften},\n id = {08d505c5-be9f-3f5c-96ee-3822c9c0d860},\n created = {2025-04-12T18:01:10.179Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T18:04:06.297Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {A powerful operational paradigm for distributed quantum information processing involves manipulating pre-shared entanglement by local operations and classical communication (LOCC). The LOCC round complexity of a given task describes how many rounds of classical communication are needed to complete the task. Despite some results separating one-round versus two-round protocols, very little is known about higher round complexities. In this paper, we revisit the task of one-shot random-party entanglement distillation as a way to highlight some interesting features of LOCC round complexity. We first show that for random-party distillation in three qubits, the number of communication rounds needed in an optimal protocol depends on the entanglement measure used; for the same fixed state some entanglement measures need only two rounds to maximize whereas others need an unbounded number of rounds. In doing so, we construct a family of LOCC instruments that require an unbounded number of rounds to implement. We then prove explicit tight lower bounds on the LOCC round number as a function of distillation success probability. Our calculations show that the original W-state random distillation protocol by Fortescue and Lo is essentially optimal in terms of round complexity.},\n bibtype = {article},\n author = {Liu, Guangkuo and George, Ian and Chitambar, Eric},\n doi = {10.22331/Q-2023-09-07-1104},\n journal = {Quantum}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  A powerful operational paradigm for distributed quantum information processing involves manipulating pre-shared entanglement by local operations and classical communication (LOCC). The LOCC round complexity of a given task describes how many rounds of classical communication are needed to complete the task. Despite some results separating one-round versus two-round protocols, very little is known about higher round complexities. In this paper, we revisit the task of one-shot random-party entanglement distillation as a way to highlight some interesting features of LOCC round complexity. We first show that for random-party distillation in three qubits, the number of communication rounds needed in an optimal protocol depends on the entanglement measure used; for the same fixed state some entanglement measures need only two rounds to maximize whereas others need an unbounded number of rounds. In doing so, we construct a family of LOCC instruments that require an unbounded number of rounds to implement. We then prove explicit tight lower bounds on the LOCC round number as a function of distillation success probability. Our calculations show that the original W-state random distillation protocol by Fortescue and Lo is essentially optimal in terms of round complexity.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2022\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2022')\"\n      onkeypress=\"toggleGroup('group_2022')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2022</span>\n      <span class=\"bibbase_group_count\">\n        \n        (4)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"zhang-chen-chitambar-buildingmultipleaccesschannelswithasingleparticle-2022\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/08210d90-275e-4e81-36fd-dfe2d9ecb1e7/Chitambar_2022_Building_Multiple_Access_Channels_with_a_Sing.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'zhang-chen-chitambar-buildingmultipleaccesschannelswithasingleparticle-2022', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/08210d90-275e-4e81-36fd-dfe2d9ecb1e7/Chitambar_2022_Building_Multiple_Access_Channels_with_a_Sing.pdf.pdf', event);\">\n    Building Multiple Access Channels with a Single Particle.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Zhang,  Y.; Chen,  X.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Quantum</i>, 6.  2022.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/08210d90-275e-4e81-36fd-dfe2d9ecb1e7/Chitambar_2022_Building_Multiple_Access_Channels_with_a_Sing.pdf.pdf\"\n     onclick=\"log_download('zhang-chen-chitambar-buildingmultipleaccesschannelswithasingleparticle-2022', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/08210d90-275e-4e81-36fd-dfe2d9ecb1e7/Chitambar_2022_Building_Multiple_Access_Channels_with_a_Sing.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Building Multiple Access Channels with a Single Particle [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.22331/Q-2022-02-16-653\"\n     onclick=\"log_download('zhang-chen-chitambar-buildingmultipleaccesschannelswithasingleparticle-2022', 'http://doi.org/10.22331/Q-2022-02-16-653', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/zhang-chen-chitambar-buildingmultipleaccesschannelswithasingleparticle-2022\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('zhang-chen-chitambar-buildingmultipleaccesschannelswithasingleparticle-2022')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Building Multiple Access Channels with a Single Particle},\n type = {article},\n year = {2022},\n volume = {6},\n publisher = {Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften},\n id = {4f4a3703-5a5f-3776-8e5a-3fe9784a02ea},\n created = {2025-04-11T23:19:49.064Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T18:11:37.156Z},\n read = {true},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {A multiple access channel describes a situation in which multiple senders are trying to forward messages to a single receiver using some physical medium. In this paper we consider scenarios in which this medium consists of just a single classical or quantum particle. In the quantum case, the particle can be prepared in a superposition state thereby allowing for a richer family of encoding strategies. To make the comparison between quantum and classical channels precise, we introduce an operational framework in which all possible encoding strategies consume no more than a single particle. We apply this framework to an Nport interferometer experiment in which each party controls a path the particle can traverse. When used for the purpose of communication, this setup embodies a multiple access channel (MAC) built with a single particle. We provide a full characterization of the Nparty classical MACs that can be built from a single particle, and we show that every quantum particle can generate a MAC outside the classical set. To further distinguish the capabilities of a single classical and quantum particle, we relax the locality constraint and allow for joint encodings by subsets of 1 &lt; K ≤ N parties. This generates a richer family of classical MACs whose polytope dimension we compute. We identify a &quot;generalized fingerprinting inequality&quot; as a valid facet for this polytope, and we verify that a quantum particle distributed among N separated parties can violate this inequality even when K = N-1. Connections are drawn between the single-particle framework and multi-level coherence theory. We show that every pure state with K-level coherence can be detected in a semi-device independent manner, with the only assumption being conservation of particle number.},\n bibtype = {article},\n author = {Zhang, Yujie and Chen, Xinan and Chitambar, Eric},\n doi = {10.22331/Q-2022-02-16-653},\n journal = {Quantum}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  A multiple access channel describes a situation in which multiple senders are trying to forward messages to a single receiver using some physical medium. In this paper we consider scenarios in which this medium consists of just a single classical or quantum particle. In the quantum case, the particle can be prepared in a superposition state thereby allowing for a richer family of encoding strategies. To make the comparison between quantum and classical channels precise, we introduce an operational framework in which all possible encoding strategies consume no more than a single particle. We apply this framework to an Nport interferometer experiment in which each party controls a path the particle can traverse. When used for the purpose of communication, this setup embodies a multiple access channel (MAC) built with a single particle. We provide a full characterization of the Nparty classical MACs that can be built from a single particle, and we show that every quantum particle can generate a MAC outside the classical set. To further distinguish the capabilities of a single classical and quantum particle, we relax the locality constraint and allow for joint encodings by subsets of 1 < K ≤ N parties. This generates a richer family of classical MACs whose polytope dimension we compute. We identify a \"generalized fingerprinting inequality\" as a valid facet for this polytope, and we verify that a quantum particle distributed among N separated parties can violate this inequality even when K = N-1. Connections are drawn between the single-particle framework and multi-level coherence theory. We show that every pure state with K-level coherence can be detected in a semi-device independent manner, with the only assumption being conservation of particle number.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"zeitler-chapman-chitambar-kwiat-entanglementverificationofhyperentangledphotonpairs-2022\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/435b4d80-b466-54b7-3467-756ef36af973/Zeitler_2022_Entanglement_Verification_of_Hyperentangled_Pho.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'zeitler-chapman-chitambar-kwiat-entanglementverificationofhyperentangledphotonpairs-2022', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/435b4d80-b466-54b7-3467-756ef36af973/Zeitler_2022_Entanglement_Verification_of_Hyperentangled_Pho.pdf.pdf', event);\">\n    Entanglement Verification of Hyperentangled Photon Pairs.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Zeitler,  C., K.; Chapman,  J., C.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Kwiat,  P., G.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Applied</i>, 18(5). 11 2022.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/435b4d80-b466-54b7-3467-756ef36af973/Zeitler_2022_Entanglement_Verification_of_Hyperentangled_Pho.pdf.pdf\"\n     onclick=\"log_download('zeitler-chapman-chitambar-kwiat-entanglementverificationofhyperentangledphotonpairs-2022', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/435b4d80-b466-54b7-3467-756ef36af973/Zeitler_2022_Entanglement_Verification_of_Hyperentangled_Pho.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Entanglement Verification of Hyperentangled Photon Pairs [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevApplied.18.054025\"\n     onclick=\"log_download('zeitler-chapman-chitambar-kwiat-entanglementverificationofhyperentangledphotonpairs-2022', 'http://doi.org/10.1103/PhysRevApplied.18.054025', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/zeitler-chapman-chitambar-kwiat-entanglementverificationofhyperentangledphotonpairs-2022\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('zeitler-chapman-chitambar-kwiat-entanglementverificationofhyperentangledphotonpairs-2022')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Entanglement Verification of Hyperentangled Photon Pairs},\n type = {article},\n year = {2022},\n volume = {18},\n month = {11},\n publisher = {American Physical Society},\n day = {1},\n id = {8a9f051f-b0dc-3315-8b21-18ed127a5b67},\n created = {2025-04-12T17:53:42.945Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T18:04:22.009Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {We experimentally investigate the properties of hyperentangled states displaying simultaneous entanglement in multiple degrees of freedom and find that Bell tests beyond the standard Clauser-Horne-Shimony-Holt inequality can reveal a higher-dimensional nature in a device-independent way. Specifically, we show that hyperentangled states possess more than just simultaneous entanglement in separate degrees of freedom but also entanglement in a higher-dimensional Hilbert space. We also verify the steerability of hyperentangled quantum states by steering different photonic degrees of freedom.},\n bibtype = {article},\n author = {Zeitler, Christopher K. and Chapman, Joseph C. and Chitambar, Eric and Kwiat, Paul G.},\n doi = {10.1103/PhysRevApplied.18.054025},\n journal = {Physical Review Applied},\n number = {5}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  We experimentally investigate the properties of hyperentangled states displaying simultaneous entanglement in multiple degrees of freedom and find that Bell tests beyond the standard Clauser-Horne-Shimony-Holt inequality can reveal a higher-dimensional nature in a device-independent way. Specifically, we show that hyperentangled states possess more than just simultaneous entanglement in separate degrees of freedom but also entanglement in a higher-dimensional Hilbert space. We also verify the steerability of hyperentangled quantum states by steering different photonic degrees of freedom.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"kim-chitambar-processoptimizedphasecovariantquantumcloning-2022\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/5fafc9ea-ed7e-50d9-1676-77134cec4193/Kim_2022_Process_optimized_phase_covariant_quantum_cloning.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'kim-chitambar-processoptimizedphasecovariantquantumcloning-2022', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/5fafc9ea-ed7e-50d9-1676-77134cec4193/Kim_2022_Process_optimized_phase_covariant_quantum_cloning.pdf.pdf', event);\">\n    Process-optimized phase-covariant quantum cloning.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Kim,  C.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 106(2). 8 2022.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/5fafc9ea-ed7e-50d9-1676-77134cec4193/Kim_2022_Process_optimized_phase_covariant_quantum_cloning.pdf.pdf\"\n     onclick=\"log_download('kim-chitambar-processoptimizedphasecovariantquantumcloning-2022', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/5fafc9ea-ed7e-50d9-1676-77134cec4193/Kim_2022_Process_optimized_phase_covariant_quantum_cloning.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Process-optimized phase-covariant quantum cloning [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.106.022405\"\n     onclick=\"log_download('kim-chitambar-processoptimizedphasecovariantquantumcloning-2022', 'http://doi.org/10.1103/PhysRevA.106.022405', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/kim-chitambar-processoptimizedphasecovariantquantumcloning-2022\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('kim-chitambar-processoptimizedphasecovariantquantumcloning-2022')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Process-optimized phase-covariant quantum cloning},\n type = {article},\n year = {2022},\n volume = {106},\n month = {8},\n publisher = {American Physical Society},\n day = {1},\n id = {71a72245-5ac8-3607-a817-ba8988e88461},\n created = {2025-04-12T18:01:03.461Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T18:04:26.628Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {After the appearance of the no-cloning theorem, approximate quantum cloning machines (QCMs) has become a well-studied subject in quantum information theory. Among several measures to quantify the performance of a QCM, single-qudit fidelity and global fidelity have been most widely used. In this paper we compute the optimal global fidelity for phase-covariant cloning machines via semidefinite programming optimization, thereby completing a remaining gap in the previous results on QCMs. We also consider optimal simulations of the cloning and transpose cloning map, both by a direct optimization and by a composition of component-wise optimal QCMs. For the cloning map the composition method is suboptimal whereas for the transpose cloning map the method is asymptotically optimal.},\n bibtype = {article},\n author = {Kim, Chloe and Chitambar, Eric},\n doi = {10.1103/PhysRevA.106.022405},\n journal = {Physical Review A},\n number = {2}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  After the appearance of the no-cloning theorem, approximate quantum cloning machines (QCMs) has become a well-studied subject in quantum information theory. Among several measures to quantify the performance of a QCM, single-qudit fidelity and global fidelity have been most widely used. In this paper we compute the optimal global fidelity for phase-covariant cloning machines via semidefinite programming optimization, thereby completing a remaining gap in the previous results on QCMs. We also consider optimal simulations of the cloning and transpose cloning map, both by a direct optimization and by a composition of component-wise optimal QCMs. For the cloning map the composition method is suboptimal whereas for the transpose cloning map the method is asymptotically optimal.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"czupryniak-chitambar-steinmetz-jordan-quantumtelescopyclockgames-2022\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/1e9c8e72-8a22-a2d3-023d-d540affc42bf/Czupryniak_2022_Quantum_telescopy_clock_games.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'czupryniak-chitambar-steinmetz-jordan-quantumtelescopyclockgames-2022', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/1e9c8e72-8a22-a2d3-023d-d540affc42bf/Czupryniak_2022_Quantum_telescopy_clock_games.pdf.pdf', event);\">\n    Quantum telescopy clock games.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Czupryniak,  R.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Steinmetz,  J.;  and Jordan,  A., N.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 106(3). 9 2022.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/1e9c8e72-8a22-a2d3-023d-d540affc42bf/Czupryniak_2022_Quantum_telescopy_clock_games.pdf.pdf\"\n     onclick=\"log_download('czupryniak-chitambar-steinmetz-jordan-quantumtelescopyclockgames-2022', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/1e9c8e72-8a22-a2d3-023d-d540affc42bf/Czupryniak_2022_Quantum_telescopy_clock_games.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Quantum telescopy clock games [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.106.032424\"\n     onclick=\"log_download('czupryniak-chitambar-steinmetz-jordan-quantumtelescopyclockgames-2022', 'http://doi.org/10.1103/PhysRevA.106.032424', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/czupryniak-chitambar-steinmetz-jordan-quantumtelescopyclockgames-2022\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('czupryniak-chitambar-steinmetz-jordan-quantumtelescopyclockgames-2022')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Quantum telescopy clock games},\n type = {article},\n year = {2022},\n volume = {106},\n month = {9},\n publisher = {American Physical Society},\n day = {1},\n id = {ebbc76a5-436e-3500-a6a6-9e0e5183a6e0},\n created = {2025-04-12T18:01:03.649Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T18:04:31.535Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {We consider the clock game-a task formulated in the framework of quantum information theory - that can be used to improve the existing schemes of quantum-enhanced telescopy. The problem of learning when a stellar photon reaches a telescope is translated into an abstract game, which we call the clock game. A winning strategy is provided that involves performing a quantum non-demolition measurement that verifies which stellar spatio-temporal modes are occupied by a photon without disturbing the phase information. We prove tight lower bounds on the entanglement cost needed to win the clock game, with the amount of necessary entangled bits equaling the number of time bins being distinguished. This lower bound on the entanglement cost applies to any telescopy protocol that aims to nondestructively extract the time bin information of an incident photon through local measurements, and our result implies that the protocol of Khabiboulline et al. [Phys. Rev. Lett. 123, 070504 (2019)0031-900710.1103/PhysRevLett.123.070504] is optimal in terms of entanglement consumption. The full task of the phase extraction is also considered, and we show that the quantum Fisher information of the stellar phase can be achieved by local measurements and shared entanglement without the necessity of nonlinear optical operations. The optimal phase measurement is achieved asymptotically with increasing number of ancilla qubits, whereas a single qubit pair is required if nonlinear operations are allowed.},\n bibtype = {article},\n author = {Czupryniak, Robert and Chitambar, Eric and Steinmetz, John and Jordan, Andrew N.},\n doi = {10.1103/PhysRevA.106.032424},\n journal = {Physical Review A},\n number = {3}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  We consider the clock game-a task formulated in the framework of quantum information theory - that can be used to improve the existing schemes of quantum-enhanced telescopy. The problem of learning when a stellar photon reaches a telescope is translated into an abstract game, which we call the clock game. A winning strategy is provided that involves performing a quantum non-demolition measurement that verifies which stellar spatio-temporal modes are occupied by a photon without disturbing the phase information. We prove tight lower bounds on the entanglement cost needed to win the clock game, with the amount of necessary entangled bits equaling the number of time bins being distinguished. This lower bound on the entanglement cost applies to any telescopy protocol that aims to nondestructively extract the time bin information of an incident photon through local measurements, and our result implies that the protocol of Khabiboulline et al. [Phys. Rev. Lett. 123, 070504 (2019)0031-900710.1103/PhysRevLett.123.070504] is optimal in terms of entanglement consumption. The full task of the phase extraction is also considered, and we show that the quantum Fisher information of the stellar phase can be achieved by local measurements and shared entanglement without the necessity of nonlinear optical operations. The optimal phase measurement is achieved asymptotically with increasing number of ancilla qubits, whereas a single qubit pair is required if nonlinear operations are allowed.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2021\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2021')\"\n      onkeypress=\"toggleGroup('group_2021')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2021</span>\n      <span class=\"bibbase_group_count\">\n        \n        (3)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"doolittle-chitambar-certifyingtheclassicalsimulationcostofaquantumchannel-2021\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7c69caa1-840f-c0a7-6e05-336e130c43eb/Doolittle_2021_Certifying_the_classical_simulation_cost_of_a.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'doolittle-chitambar-certifyingtheclassicalsimulationcostofaquantumchannel-2021', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7c69caa1-840f-c0a7-6e05-336e130c43eb/Doolittle_2021_Certifying_the_classical_simulation_cost_of_a.pdf.pdf', event);\">\n    Certifying the classical simulation cost of a quantum channel.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Doolittle,  B.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Research</i>, 3(4). 12 2021.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7c69caa1-840f-c0a7-6e05-336e130c43eb/Doolittle_2021_Certifying_the_classical_simulation_cost_of_a.pdf.pdf\"\n     onclick=\"log_download('doolittle-chitambar-certifyingtheclassicalsimulationcostofaquantumchannel-2021', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7c69caa1-840f-c0a7-6e05-336e130c43eb/Doolittle_2021_Certifying_the_classical_simulation_cost_of_a.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Certifying the classical simulation cost of a quantum channel [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevResearch.3.043073\"\n     onclick=\"log_download('doolittle-chitambar-certifyingtheclassicalsimulationcostofaquantumchannel-2021', 'http://doi.org/10.1103/PhysRevResearch.3.043073', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/doolittle-chitambar-certifyingtheclassicalsimulationcostofaquantumchannel-2021\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('doolittle-chitambar-certifyingtheclassicalsimulationcostofaquantumchannel-2021')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Certifying the classical simulation cost of a quantum channel},\n type = {article},\n year = {2021},\n volume = {3},\n month = {12},\n publisher = {American Physical Society},\n day = {1},\n id = {12f24a7c-b1a5-339f-8f03-334ad0e1dbc5},\n created = {2025-04-12T18:01:04.723Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T18:04:35.993Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {A fundamental objective in quantum information science is to determine the cost in classical resources of simulating a particular quantum system. The classical simulation cost is quantified by the signaling dimension which specifies the minimum amount of classical communication needed to perfectly simulate a channel&#x27;s input-output correlations when unlimited shared randomness is held between encoder and decoder. This paper provides a collection of device-independent tests that place lower and upper bounds on the signaling dimension of a channel. Among them, a single family of tests is shown to determine when a noisy classical channel can be simulated using an amount of communication strictly less than either its input or its output alphabet size. In addition, a family of eight signaling dimension witnesses is presented that completely characterize when any four-outcome measurement channel, such as a Bell measurement, can be simulated using one communication bit and shared randomness. Finally, we bound the signaling dimension for all partial replacer channels in d dimensions. The bounds are found to be tight for the special case of the erasure channel.},\n bibtype = {article},\n author = {Doolittle, Brian and Chitambar, Eric},\n doi = {10.1103/PhysRevResearch.3.043073},\n journal = {Physical Review Research},\n number = {4}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  A fundamental objective in quantum information science is to determine the cost in classical resources of simulating a particular quantum system. The classical simulation cost is quantified by the signaling dimension which specifies the minimum amount of classical communication needed to perfectly simulate a channel's input-output correlations when unlimited shared randomness is held between encoder and decoder. This paper provides a collection of device-independent tests that place lower and upper bounds on the signaling dimension of a channel. Among them, a single family of tests is shown to determine when a noisy classical channel can be simulated using an amount of communication strictly less than either its input or its output alphabet size. In addition, a family of eight signaling dimension witnesses is presented that completely characterize when any four-outcome measurement channel, such as a Bell measurement, can be simulated using one communication bit and shared randomness. Finally, we bound the signaling dimension for all partial replacer channels in d dimensions. The bounds are found to be tight for the special case of the erasure channel.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-gour-sengupta-zibakhsh-quantumbellnonlocalityasaformofentanglement-2021\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/51bedf13-11b9-3acd-7415-609973fc8dbf/Chitambar_2021_Quantum_Bell_nonlocality_as_a_form_of_entangl.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'chitambar-gour-sengupta-zibakhsh-quantumbellnonlocalityasaformofentanglement-2021', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/51bedf13-11b9-3acd-7415-609973fc8dbf/Chitambar_2021_Quantum_Bell_nonlocality_as_a_form_of_entangl.pdf.pdf', event);\">\n    Quantum Bell nonlocality as a form of entanglement.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Gour,  G.; Sengupta,  K.;  and Zibakhsh,  R.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 104(5). 11 2021.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/51bedf13-11b9-3acd-7415-609973fc8dbf/Chitambar_2021_Quantum_Bell_nonlocality_as_a_form_of_entangl.pdf.pdf\"\n     onclick=\"log_download('chitambar-gour-sengupta-zibakhsh-quantumbellnonlocalityasaformofentanglement-2021', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/51bedf13-11b9-3acd-7415-609973fc8dbf/Chitambar_2021_Quantum_Bell_nonlocality_as_a_form_of_entangl.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Quantum Bell nonlocality as a form of entanglement [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.104.052208\"\n     onclick=\"log_download('chitambar-gour-sengupta-zibakhsh-quantumbellnonlocalityasaformofentanglement-2021', 'http://doi.org/10.1103/PhysRevA.104.052208', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-gour-sengupta-zibakhsh-quantumbellnonlocalityasaformofentanglement-2021\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-gour-sengupta-zibakhsh-quantumbellnonlocalityasaformofentanglement-2021')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Quantum Bell nonlocality as a form of entanglement},\n type = {article},\n year = {2021},\n volume = {104},\n month = {11},\n publisher = {American Physical Society},\n day = {1},\n id = {3149dae2-6486-3227-866c-8d53a9798d7b},\n created = {2025-04-12T18:01:33.606Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T18:04:40.733Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Bell nonlocality describes a manifestation of quantum mechanics that cannot be explained by any local hidden variable model. Its origin lies in the nature of quantum entanglement, although understanding the precise relationship between nonlocality and entanglement has been a notorious open problem. In this paper, we develop a dynamical framework in which quantum Bell nonlocality emerges as a special form of entanglement and both are unified as resources under local operations and classical communication (LOCC). Our framework is built on the notion of classical and quantum processes, which are defined as channels that map elements between specific intervals in space and time. Entanglement is identified as a process that cannot be generated by LOCC while Bell nonlocality is the subset of these processes that have an instantaneous input-to-output delay time. LOCC preprocessing is a natural set of free operations in this theory, thereby providing previous nonlocality activation results a clear resource-theoretic foundation. We provide a systematic method to quantify the Bell nonlocality of a bipartite quantum channel. It is shown that both the relative entropy and the max relative entropy of nonlocality are nonadditive for a family of bipartite classical channels. This family includes the channel obtained when using the singlet state to maximally violate the CHSH inequality. We also find that the regularized relative entropy of Bell nonlocality provides an upper bound on the asymptotic rate of converting (i.e., simulating) many copies of one classical instantaneous resource to another.},\n bibtype = {article},\n author = {Chitambar, Eric and Gour, Gilad and Sengupta, Kuntal and Zibakhsh, Rana},\n doi = {10.1103/PhysRevA.104.052208},\n journal = {Physical Review A},\n number = {5}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Bell nonlocality describes a manifestation of quantum mechanics that cannot be explained by any local hidden variable model. Its origin lies in the nature of quantum entanglement, although understanding the precise relationship between nonlocality and entanglement has been a notorious open problem. In this paper, we develop a dynamical framework in which quantum Bell nonlocality emerges as a special form of entanglement and both are unified as resources under local operations and classical communication (LOCC). Our framework is built on the notion of classical and quantum processes, which are defined as channels that map elements between specific intervals in space and time. Entanglement is identified as a process that cannot be generated by LOCC while Bell nonlocality is the subset of these processes that have an instantaneous input-to-output delay time. LOCC preprocessing is a natural set of free operations in this theory, thereby providing previous nonlocality activation results a clear resource-theoretic foundation. We provide a systematic method to quantify the Bell nonlocality of a bipartite quantum channel. It is shown that both the relative entropy and the max relative entropy of nonlocality are nonadditive for a family of bipartite classical channels. This family includes the channel obtained when using the singlet state to maximally violate the CHSH inequality. We also find that the regularized relative entropy of Bell nonlocality provides an upper bound on the asymptotic rate of converting (i.e., simulating) many copies of one classical instantaneous resource to another.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"pollock-wang-chitambar-entanglementofassistanceinthreequbitsystems-2021\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7e45f887-2932-9525-20f6-bc5ce04d875b/Pollock_2021_Entanglement_of_assistance_in_three_qubit_sys_1.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'pollock-wang-chitambar-entanglementofassistanceinthreequbitsystems-2021', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7e45f887-2932-9525-20f6-bc5ce04d875b/Pollock_2021_Entanglement_of_assistance_in_three_qubit_sys_1.pdf.pdf', event);\">\n    Entanglement of assistance in three-qubit systems.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Pollock,  K.; Wang,  G.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 103(3). 3 2021.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7e45f887-2932-9525-20f6-bc5ce04d875b/Pollock_2021_Entanglement_of_assistance_in_three_qubit_sys_1.pdf.pdf\"\n     onclick=\"log_download('pollock-wang-chitambar-entanglementofassistanceinthreequbitsystems-2021', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/7e45f887-2932-9525-20f6-bc5ce04d875b/Pollock_2021_Entanglement_of_assistance_in_three_qubit_sys_1.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Entanglement of assistance in three-qubit systems [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.103.032428\"\n     onclick=\"log_download('pollock-wang-chitambar-entanglementofassistanceinthreequbitsystems-2021', 'http://doi.org/10.1103/PhysRevA.103.032428', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/pollock-wang-chitambar-entanglementofassistanceinthreequbitsystems-2021\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('pollock-wang-chitambar-entanglementofassistanceinthreequbitsystems-2021')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Entanglement of assistance in three-qubit systems},\n type = {article},\n year = {2021},\n volume = {103},\n month = {3},\n publisher = {American Physical Society},\n day = {1},\n id = {30a20f92-add7-389f-b1cd-e8064e0fe4a1},\n created = {2025-04-12T18:06:35.114Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-12T18:06:50.194Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {The entanglement of assistance quantifies the amount of entanglement that can be concentrated among a group of spatially separated parties using the assistance of some auxiliary system. In this paper we study the entanglement of assistance in the simplest scenario of three qubits. We consider how much entanglement is lost when the helper party becomes uncoupled by local measurement and classical communication. For three-qubit pure states, it is found that lossless decoupling is always possible when entanglement is quantified by the maximum probability of locally generating a Bell state. However, with respect to most other entanglement measures, such as concurrence and entanglement entropy, a lossless decoupling of the helper is possible only for a special family of states that we fully characterize.},\n bibtype = {article},\n author = {Pollock, Klee and Wang, Ge and Chitambar, Eric},\n doi = {10.1103/PhysRevA.103.032428},\n journal = {Physical Review A},\n number = {3}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  The entanglement of assistance quantifies the amount of entanglement that can be concentrated among a group of spatially separated parties using the assistance of some auxiliary system. In this paper we study the entanglement of assistance in the simplest scenario of three qubits. We consider how much entanglement is lost when the helper party becomes uncoupled by local measurement and classical communication. For three-qubit pure states, it is found that lossless decoupling is always possible when entanglement is quantified by the maximum probability of locally generating a Bell state. However, with respect to most other entanglement measures, such as concurrence and entanglement entropy, a lossless decoupling of the helper is possible only for a special family of states that we fully characterize.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2020\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2020')\"\n      onkeypress=\"toggleGroup('group_2020')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2020</span>\n      <span class=\"bibbase_group_count\">\n        \n        (6)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"gonzales-chitambar-boundsoninstantaneousnonlocalquantumcomputation-2020\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Bounds on Instantaneous Nonlocal Quantum Computation.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Gonzales,  A.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>IEEE Transactions on Information Theory</i>, 66(5).  2020.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1109/TIT.2019.2950190\"\n     onclick=\"log_download('gonzales-chitambar-boundsoninstantaneousnonlocalquantumcomputation-2020', 'http://doi.org/10.1109/TIT.2019.2950190', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/gonzales-chitambar-boundsoninstantaneousnonlocalquantumcomputation-2020\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>10 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('gonzales-chitambar-boundsoninstantaneousnonlocalquantumcomputation-2020')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Bounds on Instantaneous Nonlocal Quantum Computation},\n type = {article},\n year = {2020},\n keywords = {Quantum entanglement,quantum computing,teleportation},\n volume = {66},\n id = {f1f63484-2a06-357f-9ed5-e7abb9843e18},\n created = {2020-08-20T19:55:39.652Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.652Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 1963-2012 IEEE. Instantaneous nonlocal quantum computation refers to a process in which spacelike separated parties simulate a nonlocal quantum operation on their joint systems through the consumption of pre-shared entanglement. To prevent a violation of causality, this simulation succeeds up to local errors that can only be corrected after the parties communicate classically with one another. However, this communication is non-interactive, and it involves just the broadcasting of local measurement outcomes. We refer to this operational paradigm as local operations and broadcast communication (LOBC) to distinguish it from the standard local operations and (interactive) classical communication (LOCC). In this paper, we show that an arbitrary two-qubit gate can be implemented by LOBC with $\\epsilon $ -error using $O(\\log (1/\\epsilon))$ entangled bits (ebits). This offers an exponential improvement over the best known two-qubit protocols, whose ebit costs behave as $O(1/\\epsilon)$. We also consider the family of binary controlled gates on dimensions $d_A\\otimes d_B$. We find that any hermitian gate of this form can be implemented by LOBC using a single shared ebit. In sharp contrast, a lower bound of $\\log d_B$ ebits is shown in the case of generic (i.e. non-hermitian) gates from this family, even when $d_A=2$. This demonstrates an unbounded gap between the entanglement costs of LOCC and LOBC gate implementation. Whereas previous lower bounds on the entanglement cost for instantaneous nonlocal computation restrict the minimum dimension of the needed entanglement, we bound its entanglement entropy. To our knowledge this is the first such lower bound of its kind.},\n bibtype = {article},\n author = {Gonzales, A. and Chitambar, E.},\n doi = {10.1109/TIT.2019.2950190},\n journal = {IEEE Transactions on Information Theory},\n number = {5}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 1963-2012 IEEE. Instantaneous nonlocal quantum computation refers to a process in which spacelike separated parties simulate a nonlocal quantum operation on their joint systems through the consumption of pre-shared entanglement. To prevent a violation of causality, this simulation succeeds up to local errors that can only be corrected after the parties communicate classically with one another. However, this communication is non-interactive, and it involves just the broadcasting of local measurement outcomes. We refer to this operational paradigm as local operations and broadcast communication (LOBC) to distinguish it from the standard local operations and (interactive) classical communication (LOCC). In this paper, we show that an arbitrary two-qubit gate can be implemented by LOBC with $\\epsilon $ -error using $O(\\log (1/\\epsilon))$ entangled bits (ebits). This offers an exponential improvement over the best known two-qubit protocols, whose ebit costs behave as $O(1/\\epsilon)$. We also consider the family of binary controlled gates on dimensions $d_A\\otimes d_B$. We find that any hermitian gate of this form can be implemented by LOBC using a single shared ebit. In sharp contrast, a lower bound of $\\log d_B$ ebits is shown in the case of generic (i.e. non-hermitian) gates from this family, even when $d_A=2$. This demonstrates an unbounded gap between the entanglement costs of LOCC and LOBC gate implementation. Whereas previous lower bounds on the entanglement cost for instantaneous nonlocal computation restrict the minimum dimension of the needed entanglement, we bound its entanglement entropy. To our knowledge this is the first such lower bound of its kind.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"buscemi-chitambar-zhou-completeresourcetheoryofquantumincompatibilityasquantumprogrammability-2020\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Complete Resource Theory of Quantum Incompatibility as Quantum Programmability.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Buscemi,  F.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Zhou,  W.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 124(12).  2020.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.124.120401\"\n     onclick=\"log_download('buscemi-chitambar-zhou-completeresourcetheoryofquantumincompatibilityasquantumprogrammability-2020', 'http://doi.org/10.1103/PhysRevLett.124.120401', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/buscemi-chitambar-zhou-completeresourcetheoryofquantumincompatibilityasquantumprogrammability-2020\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('buscemi-chitambar-zhou-completeresourcetheoryofquantumincompatibilityasquantumprogrammability-2020')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Complete Resource Theory of Quantum Incompatibility as Quantum Programmability},\n type = {article},\n year = {2020},\n volume = {124},\n id = {940a84ef-16a7-39bc-a6c7-976cccd706f0},\n created = {2020-08-20T19:55:39.959Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.959Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2020 American Physical Society. Measurement incompatibility describes two or more quantum measurements whose expected joint outcome on a given system cannot be defined. This purely nonclassical phenomenon provides a necessary ingredient in many quantum information tasks such as violating a Bell inequality or nonlocally steering part of an entangled state. In this Letter, we characterize incompatibility in terms of programmable measurement devices and the general notion of quantum programmability. This refers to the temporal freedom a user has in issuing programs to a quantum device. For devices with a classical control and classical output, measurement incompatibility emerges as the essential quantum resource embodied in their functioning. Based on the processing of programmable measurement devices, we construct a quantum resource theory of incompatibility. A complete set of convertibility conditions for programmable devices is derived based on quantum state discrimination with postmeasurement information.},\n bibtype = {article},\n author = {Buscemi, F. and Chitambar, E. and Zhou, W.},\n doi = {10.1103/PhysRevLett.124.120401},\n journal = {Physical Review Letters},\n number = {12}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2020 American Physical Society. Measurement incompatibility describes two or more quantum measurements whose expected joint outcome on a given system cannot be defined. This purely nonclassical phenomenon provides a necessary ingredient in many quantum information tasks such as violating a Bell inequality or nonlocally steering part of an entangled state. In this Letter, we characterize incompatibility in terms of programmable measurement devices and the general notion of quantum programmability. This refers to the temporal freedom a user has in issuing programs to a quantum device. For devices with a classical control and classical output, measurement incompatibility emerges as the essential quantum resource embodied in their functioning. Based on the processing of programmable measurement devices, we construct a quantum resource theory of incompatibility. A complete set of convertibility conditions for programmable devices is derived based on quantum state discrimination with postmeasurement information.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"zhang-bravo-lorenz-chitambar-channelactivationofchshnonlocality-2020\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Channel activation of CHSH nonlocality.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Zhang,  Y.; Bravo,  R.; Lorenz,  V.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>New Journal of Physics</i>, 22(4).  2020.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1088/1367-2630/ab7bef\"\n     onclick=\"log_download('zhang-bravo-lorenz-chitambar-channelactivationofchshnonlocality-2020', 'http://doi.org/10.1088/1367-2630/ab7bef', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/zhang-bravo-lorenz-chitambar-channelactivationofchshnonlocality-2020\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>7 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('zhang-bravo-lorenz-chitambar-channelactivationofchshnonlocality-2020')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Channel activation of CHSH nonlocality},\n type = {article},\n year = {2020},\n keywords = {Chsh breaking channel,Nonlocality breaking channel,Superactivation},\n volume = {22},\n id = {b44e6ebc-ae9f-39e8-b625-f296dc8897e3},\n created = {2020-08-20T19:55:40.385Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.385Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2020 The Author(s). Published by IOP Publishing Ltd on behalf of the Institute of Physics and Deutsche Physikalische Gesellschaft. Quantum channels that break CHSH nonlocality on all input states are known as CHSH-breaking channels. In quantum networks, such channels are useless for distributing correlations that can violate the CHSH Inequality. Motivated by previous work on activation of nonlocality in quantum states, here we demonstrate an analogous activation of CHSH-breaking channels. That is, we show that certain pairs of CHSH-breaking channels are no longer CHSH-breaking when used in combination. We find that this type of activation can emerge in both uni-directional and bi-directional communication scenarios.},\n bibtype = {article},\n author = {Zhang, Y. and Bravo, R.A. and Lorenz, V.O. and Chitambar, E.},\n doi = {10.1088/1367-2630/ab7bef},\n journal = {New Journal of Physics},\n number = {4}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2020 The Author(s). Published by IOP Publishing Ltd on behalf of the Institute of Physics and Deutsche Physikalische Gesellschaft. Quantum channels that break CHSH nonlocality on all input states are known as CHSH-breaking channels. In quantum networks, such channels are useless for distributing correlations that can violate the CHSH Inequality. Motivated by previous work on activation of nonlocality in quantum states, here we demonstrate an analogous activation of CHSH-breaking channels. That is, we show that certain pairs of CHSH-breaking channels are no longer CHSH-breaking when used in combination. We find that this type of activation can emerge in both uni-directional and bi-directional communication scenarios.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-devicente-girard-gour-entanglementmanipulationbeyondlocaloperationsandclassicalcommunication-2020\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Entanglement manipulation beyond local operations and classical communication.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; De Vicente,  J.; Girard,  M.;  and Gour,  G.\n</span>\n\n  \n\n</span>\n\n  <i>Journal of Mathematical Physics</i>, 61(4).  2020.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1063/1.5124109\"\n     onclick=\"log_download('chitambar-devicente-girard-gour-entanglementmanipulationbeyondlocaloperationsandclassicalcommunication-2020', 'http://doi.org/10.1063/1.5124109', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-devicente-girard-gour-entanglementmanipulationbeyondlocaloperationsandclassicalcommunication-2020\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>21 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-devicente-girard-gour-entanglementmanipulationbeyondlocaloperationsandclassicalcommunication-2020')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Entanglement manipulation beyond local operations and classical communication},\n type = {article},\n year = {2020},\n volume = {61},\n id = {bd9a9d58-2c6a-308c-98f1-9cc68b2397f8},\n created = {2020-08-20T19:55:40.423Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.423Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2020 Author(s). When a quantum system is distributed to spatially separated parties, it is natural to consider how the system evolves when the parties perform local quantum operations with classical communication (LOCC). However, the structure of LOCC channels is exceedingly complex, leaving many important physical problems unsolved. In this paper, we consider generalized resource theories of entanglement based on different relaxations to the class of LOCC. The behavior of various entanglement measures is studied under non-entangling channels, as well as the newly introduced classes of dually non-entangling and positive partial transpose (PPT)-preserving channels. In an effort to better understand the nature of LOCC bound entanglement, we study the problem of entanglement distillation in these generalized resource theories. We first show that unlike LOCC, general non-entangling maps can be superactivated, in the sense that two copies of the same non-entangling map can, nevertheless, be entangling. On the single-copy level, we demonstrate that every NPT entangled state can be converted into an LOCC-distillable state using channels that are both dually non-entangling and having a PPT Choi representation and that every state can be converted into an LOCC-distillable state using operations belonging to any family of polytopes that approximate LOCC. We then turn to the stochastic convertibility of multipartite pure states and show that any two states can be interconverted by any polytope approximation to the set of separable channels. Finally, as an analog to k-positive maps, we introduce and analyze the set of k-non-entangling channels.},\n bibtype = {article},\n author = {Chitambar, E. and De Vicente, J.I. and Girard, M.W. and Gour, G.},\n doi = {10.1063/1.5124109},\n journal = {Journal of Mathematical Physics},\n number = {4}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2020 Author(s). When a quantum system is distributed to spatially separated parties, it is natural to consider how the system evolves when the parties perform local quantum operations with classical communication (LOCC). However, the structure of LOCC channels is exceedingly complex, leaving many important physical problems unsolved. In this paper, we consider generalized resource theories of entanglement based on different relaxations to the class of LOCC. The behavior of various entanglement measures is studied under non-entangling channels, as well as the newly introduced classes of dually non-entangling and positive partial transpose (PPT)-preserving channels. In an effort to better understand the nature of LOCC bound entanglement, we study the problem of entanglement distillation in these generalized resource theories. We first show that unlike LOCC, general non-entangling maps can be superactivated, in the sense that two copies of the same non-entangling map can, nevertheless, be entangling. On the single-copy level, we demonstrate that every NPT entangled state can be converted into an LOCC-distillable state using channels that are both dually non-entangling and having a PPT Choi representation and that every state can be converted into an LOCC-distillable state using operations belonging to any family of polytopes that approximate LOCC. We then turn to the stochastic convertibility of multipartite pure states and show that any two states can be interconverted by any polytope approximation to the set of separable channels. Finally, as an analog to k-positive maps, we introduce and analyze the set of k-non-entangling channels.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chen-chitambar-entanglementbreakingsuperchannels-2020\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Entanglement-breaking superchannels.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Chen,  S.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Quantum</i>, 4.  2020.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.22331/q-2020-07-16-299\"\n     onclick=\"log_download('chen-chitambar-entanglementbreakingsuperchannels-2020', 'http://doi.org/10.22331/q-2020-07-16-299', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chen-chitambar-entanglementbreakingsuperchannels-2020\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>1 download</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chen-chitambar-entanglementbreakingsuperchannels-2020')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Entanglement-breaking superchannels},\n type = {article},\n year = {2020},\n volume = {4},\n id = {71f44b56-76d4-3560-bf91-8fc303374b77},\n created = {2020-10-12T23:59:00.000Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-10-15T07:26:13.634Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2020 Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften. All rights reserved. In this paper we initiate the study of entanglement-breaking (EB) superchannels. These are processes that always yield separable maps when acting on one side of a bipartite completely positive (CP) map. EB superchannels are a generalization of the well-known EB channels. We give several equivalent characterizations of EB supermaps and superchannels. Unlike its channel counterpart, we find that not every EB superchannel can be implemented as a measure-and-prepare superchannel. We also demonstrate that many EB superchannels can be superactivated, in the sense that they can output non-separable channels when wired in series. We then introduce the notions of CPTP- and CP-complete images of a superchannel, which capture deterministic and probabilistic channel convertibility, respectively. This allows us to characterize the power of EB superchannels for generating CP maps in different scenarios, and it reveals some fundamental differences between channels and superchannels. Finally, we relax the definition of separable channels to include (p, q)-non-entangling channels, which are bipartite channels that cannot generate entanglement using p- and q-dimensional ancillary systems. By introducing and investigating k-EB maps, we construct examples of (p, q)-EB superchannels that are not fully entanglement breaking. Partial results on the characterization of (p, q)-EB superchannels are also provided.},\n bibtype = {article},\n author = {Chen, S. and Chitambar, E.},\n doi = {10.22331/q-2020-07-16-299},\n journal = {Quantum}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2020 Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften. All rights reserved. In this paper we initiate the study of entanglement-breaking (EB) superchannels. These are processes that always yield separable maps when acting on one side of a bipartite completely positive (CP) map. EB superchannels are a generalization of the well-known EB channels. We give several equivalent characterizations of EB supermaps and superchannels. Unlike its channel counterpart, we find that not every EB superchannel can be implemented as a measure-and-prepare superchannel. We also demonstrate that many EB superchannels can be superactivated, in the sense that they can output non-separable channels when wired in series. We then introduce the notions of CPTP- and CP-complete images of a superchannel, which capture deterministic and probabilistic channel convertibility, respectively. This allows us to characterize the power of EB superchannels for generating CP maps in different scenarios, and it reveals some fundamental differences between channels and superchannels. Finally, we relax the definition of separable channels to include (p, q)-non-entangling channels, which are bipartite channels that cannot generate entanglement using p- and q-dimensional ancillary systems. By introducing and investigating k-EB maps, we construct examples of (p, q)-EB superchannels that are not fully entanglement breaking. Partial results on the characterization of (p, q)-EB superchannels are also provided.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"saxena-chitambar-gour-dynamicalresourcetheoryofquantumcoherence-2020\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/354277b5-1b25-9c29-0403-b02eaaa899ab/Saxena_2020_Dynamical_resource_theory_of_quantum_coherence.pdf.pdf\"\n     onclick=\"return trackOutboundLink('publications', 'click', 'saxena-chitambar-gour-dynamicalresourcetheoryofquantumcoherence-2020', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/354277b5-1b25-9c29-0403-b02eaaa899ab/Saxena_2020_Dynamical_resource_theory_of_quantum_coherence.pdf.pdf', event);\">\n    Dynamical resource theory of quantum coherence.\n  </a>\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Saxena,  G.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Gour,  G.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Research</i>, 2(2). 6 2020.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n  <a href=\"https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/354277b5-1b25-9c29-0403-b02eaaa899ab/Saxena_2020_Dynamical_resource_theory_of_quantum_coherence.pdf.pdf\"\n     onclick=\"log_download('saxena-chitambar-gour-dynamicalresourcetheoryofquantumcoherence-2020', 'https://bibbase.org/service/mendeley/889ca0d7-cd8b-3818-bafe-550deb56f3f0/file/354277b5-1b25-9c29-0403-b02eaaa899ab/Saxena_2020_Dynamical_resource_theory_of_quantum_coherence.pdf.pdf', event.ctrlKey, event)\">\n    <img src=\"//bibbase.org/img/filetypes/pdf.svg\"\n\t     alt=\"Dynamical resource theory of quantum coherence [pdf]\"\n       title=\"Paper\"\n\t     class=\"bibbase_icon\"\n         ><span class=\"bibbase_icon_text\">Paper</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevResearch.2.023298\"\n     onclick=\"log_download('saxena-chitambar-gour-dynamicalresourcetheoryofquantumcoherence-2020', 'http://doi.org/10.1103/PhysRevResearch.2.023298', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/saxena-chitambar-gour-dynamicalresourcetheoryofquantumcoherence-2020\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>5 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('saxena-chitambar-gour-dynamicalresourcetheoryofquantumcoherence-2020')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Dynamical resource theory of quantum coherence},\n type = {article},\n year = {2020},\n volume = {2},\n month = {6},\n publisher = {American Physical Society},\n day = {8},\n id = {9b81b5f6-a9d1-393b-a18b-6671b35346e4},\n created = {2025-04-13T17:02:45.760Z},\n file_attached = {true},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2025-04-13T17:03:02.550Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Decoherence is all around us. Every quantum system that interacts with the environment is doomed to decohere. While preserving quantum coherence is a major challenge faced in quantum technologies, the potential benefits for information processing are very promising since coherence can lead to various operational advantages, such as in quantum algorithms. Hence, much work has been devoted in recent years to quantify the coherence present in a system. In the present paper, we formulate the quantum resource theory of dynamical coherence. The underlying physical principle we follow is that the free dynamical objects are those that neither store nor output coherence. This leads us to identify classical channels as the free elements in this theory. Consequently, even the quantum identity channel is not free as all physical systems undergo decoherence and hence, the preservation of coherence should be considered a resource. The maximally coherent channel is then the quantum Fourier transform because of its abillity to preserve entanglement and generate maximal coherence from nothing. In our work, we introduce four different types of free superchannels (analogous to MIO, DIO, IO, and SIO) and discuss in detail two of them, namely, dephasing-covariant incoherent superchannels (DISC), maximally incoherent superchannels (MISC). The latter consists of all superchannels that do not generate non-classical channels from classical ones. We quantify dynamical coherence using channel-divergence-based monotones for MISC and DISC. We show that some of these monotones have operational interpretations as the exact, the approximate, and the liberal coherence cost of a quantum channel. Moreover, we prove that the liberal asymptotic cost of a channel is equal to a new type of regularized relative entropy. Finally, we show that the conversion distance between two channels under MISC and DISC can be computed using a semidefinite program (SDP).},\n bibtype = {article},\n author = {Saxena, Gaurav and Chitambar, Eric and Gour, Gilad},\n doi = {10.1103/PhysRevResearch.2.023298},\n journal = {Physical Review Research},\n number = {2}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Decoherence is all around us. Every quantum system that interacts with the environment is doomed to decohere. While preserving quantum coherence is a major challenge faced in quantum technologies, the potential benefits for information processing are very promising since coherence can lead to various operational advantages, such as in quantum algorithms. Hence, much work has been devoted in recent years to quantify the coherence present in a system. In the present paper, we formulate the quantum resource theory of dynamical coherence. The underlying physical principle we follow is that the free dynamical objects are those that neither store nor output coherence. This leads us to identify classical channels as the free elements in this theory. Consequently, even the quantum identity channel is not free as all physical systems undergo decoherence and hence, the preservation of coherence should be considered a resource. The maximally coherent channel is then the quantum Fourier transform because of its abillity to preserve entanglement and generate maximal coherence from nothing. In our work, we introduce four different types of free superchannels (analogous to MIO, DIO, IO, and SIO) and discuss in detail two of them, namely, dephasing-covariant incoherent superchannels (DISC), maximally incoherent superchannels (MISC). The latter consists of all superchannels that do not generate non-classical channels from classical ones. We quantify dynamical coherence using channel-divergence-based monotones for MISC and DISC. We show that some of these monotones have operational interpretations as the exact, the approximate, and the liberal coherence cost of a quantum channel. Moreover, we prove that the liberal asymptotic cost of a channel is equal to a new type of regularized relative entropy. Finally, we show that the conversion distance between two channels under MISC and DISC can be computed using a semidefinite program (SDP).\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2019\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2019')\"\n      onkeypress=\"toggleGroup('group_2019')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2019</span>\n      <span class=\"bibbase_group_count\">\n        \n        (4)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"yue-chitambar-thezeroerrorentanglementcostishighlynonadditive-2019\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  The zero-error entanglement cost is highly non-additive.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Yue,  Q.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Journal of Mathematical Physics</i>, 60(11).  2019.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1063/1.5087815\"\n     onclick=\"log_download('yue-chitambar-thezeroerrorentanglementcostishighlynonadditive-2019', 'http://doi.org/10.1063/1.5087815', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/yue-chitambar-thezeroerrorentanglementcostishighlynonadditive-2019\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>4 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('yue-chitambar-thezeroerrorentanglementcostishighlynonadditive-2019')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {The zero-error entanglement cost is highly non-additive},\n type = {article},\n year = {2019},\n volume = {60},\n id = {fe105007-3da1-3889-b174-c572ef813619},\n created = {2020-08-20T19:55:39.682Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.682Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2019 Author(s). The Schmidt number is an entanglement measure whose logarithm quantifies the zero-error entanglement cost of generating a given quantum state using local operations and classical communication. In this paper, we show that the Schmidt number is highly nonmultiplicative in the sense that for any integer n, there exist states whose Schmidt number remains constant when taking n copies of the given state. These states also provide a rare instance in which the regularized zero-error entanglement cost can be computed exactly. We then explore the question of increasing the Schmidt number by quantum operations. We describe a class of bipartite quantum operations that preserve the Schmidt number for pure state transformations, and yet they can increase the Schmidt number by an arbitrarily large amount when generating mixed states. Our results are obtained by making connections to the resource theory of quantum coherence and generalizing the class of dephasing-covariant incoherent operations to the bipartite setting.},\n bibtype = {article},\n author = {Yue, Q. and Chitambar, E.},\n doi = {10.1063/1.5087815},\n journal = {Journal of Mathematical Physics},\n number = {11}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2019 Author(s). The Schmidt number is an entanglement measure whose logarithm quantifies the zero-error entanglement cost of generating a given quantum state using local operations and classical communication. In this paper, we show that the Schmidt number is highly nonmultiplicative in the sense that for any integer n, there exist states whose Schmidt number remains constant when taking n copies of the given state. These states also provide a rare instance in which the regularized zero-error entanglement cost can be computed exactly. We then explore the question of increasing the Schmidt number by quantum operations. We describe a class of bipartite quantum operations that preserve the Schmidt number for pure state transformations, and yet they can increase the Schmidt number by an arbitrarily large amount when generating mixed states. Our results are obtained by making connections to the resource theory of quantum coherence and generalizing the class of dephasing-covariant incoherent operations to the bipartite setting.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-gour-quantumresourcetheories-2019\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Quantum resource theories.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Gour,  G.\n</span>\n\n  \n\n</span>\n\n  <i>Reviews of Modern Physics</i>, 91(2).  2019.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/RevModPhys.91.025001\"\n     onclick=\"log_download('chitambar-gour-quantumresourcetheories-2019', 'http://doi.org/10.1103/RevModPhys.91.025001', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-gour-quantumresourcetheories-2019\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>10 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-gour-quantumresourcetheories-2019')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Quantum resource theories},\n type = {article},\n year = {2019},\n volume = {91},\n id = {477ef01c-0b7c-3d78-8f24-7203f9ec3770},\n created = {2020-08-20T19:55:39.697Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.697Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2019 American Physical Society. Quantum resource theories (QRTs) offer a highly versatile and powerful framework for studying different phenomena in quantum physics. From quantum entanglement to quantum computation, resource theories can be used to quantify a desirable quantum effect, develop new protocols for its detection, and identify processes that optimize its use for a given application. Particularly, QRTs have revolutionized the way we think about familiar properties of physical systems such as entanglement, elevating them from being just interesting fundamental phenomena to being useful in performing practical tasks. The basic methodology of a general QRT involves partitioning all quantum states into two groups, one consisting of free states and the other consisting of resource states. Accompanying the set of free states is a collection of free quantum operations arising from natural restrictions placed on the physical system, restrictions that force the free operations to act invariantly on the set of free states. The QRT then studies what information processing tasks become possible using the restricted operations. Despite the large degree of freedom in how one defines the free states and free operations, unexpected similarities emerge among different QRTs in terms of resource measures and resource convertibility. As a result, objects that appear quite distinct on the surface, such as entanglement and quantum reference frames, appear to have great similarity on a deeper structural level. This article reviews the general framework of a quantum resource theory, focusing on common structural features, operational tasks, and resource measures. To illustrate these concepts, an overview is provided on some of the more commonly studied QRTs in the literature.},\n bibtype = {article},\n author = {Chitambar, E. and Gour, G.},\n doi = {10.1103/RevModPhys.91.025001},\n journal = {Reviews of Modern Physics},\n number = {2}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2019 American Physical Society. Quantum resource theories (QRTs) offer a highly versatile and powerful framework for studying different phenomena in quantum physics. From quantum entanglement to quantum computation, resource theories can be used to quantify a desirable quantum effect, develop new protocols for its detection, and identify processes that optimize its use for a given application. Particularly, QRTs have revolutionized the way we think about familiar properties of physical systems such as entanglement, elevating them from being just interesting fundamental phenomena to being useful in performing practical tasks. The basic methodology of a general QRT involves partitioning all quantum states into two groups, one consisting of free states and the other consisting of resource states. Accompanying the set of free states is a collection of free quantum operations arising from natural restrictions placed on the physical system, restrictions that force the free operations to act invariantly on the set of free states. The QRT then studies what information processing tasks become possible using the restricted operations. Despite the large degree of freedom in how one defines the free states and free operations, unexpected similarities emerge among different QRTs in terms of resource measures and resource convertibility. As a result, objects that appear quite distinct on the surface, such as entanglement and quantum reference frames, appear to have great similarity on a deeper structural level. This article reviews the general framework of a quantum resource theory, focusing on common structural features, operational tasks, and resource measures. To illustrate these concepts, an overview is provided on some of the more commonly studied QRTs in the literature.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"zhao-liu-yuan-chitambar-winter-oneshotcoherencedistillationtowardscompletingthepicture-2019\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  One-Shot Coherence Distillation: Towards Completing the Picture.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Zhao,  Q.; Liu,  Y.; Yuan,  X.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Winter,  A.\n</span>\n\n  \n\n</span>\n\n  <i>IEEE Transactions on Information Theory</i>, 65(10).  2019.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1109/TIT.2019.2911102\"\n     onclick=\"log_download('zhao-liu-yuan-chitambar-winter-oneshotcoherencedistillationtowardscompletingthepicture-2019', 'http://doi.org/10.1109/TIT.2019.2911102', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/zhao-liu-yuan-chitambar-winter-oneshotcoherencedistillationtowardscompletingthepicture-2019\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>3 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('zhao-liu-yuan-chitambar-winter-oneshotcoherencedistillationtowardscompletingthepicture-2019')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {One-Shot Coherence Distillation: Towards Completing the Picture},\n type = {article},\n year = {2019},\n keywords = {Quantum coherence,coherence distillation,one-shot,quantum resource theory},\n volume = {65},\n id = {05d81eb1-a738-339e-9b07-4acb9ecdc99b},\n created = {2020-08-20T19:55:40.513Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.513Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 1963-2012 IEEE. The resource framework of quantum coherence was introduced by Baumgratz, Cramer, and Plenio [Phys. Rev. Lett. 113, 140401 (2014)] and further developed by Winter and Yang [Phys. Rev. Lett. 116, 120404 (2016)]. We consider the one-shot problem of distilling pure coherence from a single instance of a given resource state. Specifically, we determine the distillable coherence with a given fidelity under incoherent operations (IO) through a generalization of the Winter-Yang protocol. This is compared to the distillable coherence under maximal incoherent operations (MIO) and dephasing-covariant incoherent operations (DIO), which can be cast as a semidefinite programme, that has been presented previously by Regula et al. [Phys. Rev. Lett. 121, 010401 (2018)]. Our results are given in terms of a smoothed min-relative entropy distance from the incoherent set of states, and a variant of the hypothesis-testing relative entropy distance, respectively. The one-shot distillable coherence is also related to one-shot randomness extraction. Moreover, from the one-shot formulas under IO, MIO, and DIO, we can recover the optimal distillable rate in the many-copy asymptotics, yielding the relative entropy of coherence. These results can be compared with previous work by some of the present authors [Zhao et al., Phys. Rev. Lett. 120, 070403 (2018)] on one-shot coherence formation under IO, MIO, DIO and also SIO. This shows that the amount of distillable coherence is essentially the same for IO, DIO, and MIO, despite the fact that the three classes of operations are very different. We also relate the distillable coherence under strictly incoherent operations (SIO) to a constrained hypothesis testing problem and explicitly show the existence of bound coherence under SIO in the asymptotic regime.},\n bibtype = {article},\n author = {Zhao, Q. and Liu, Y. and Yuan, X. and Chitambar, E. and Winter, A.},\n doi = {10.1109/TIT.2019.2911102},\n journal = {IEEE Transactions on Information Theory},\n number = {10}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 1963-2012 IEEE. The resource framework of quantum coherence was introduced by Baumgratz, Cramer, and Plenio [Phys. Rev. Lett. 113, 140401 (2014)] and further developed by Winter and Yang [Phys. Rev. Lett. 116, 120404 (2016)]. We consider the one-shot problem of distilling pure coherence from a single instance of a given resource state. Specifically, we determine the distillable coherence with a given fidelity under incoherent operations (IO) through a generalization of the Winter-Yang protocol. This is compared to the distillable coherence under maximal incoherent operations (MIO) and dephasing-covariant incoherent operations (DIO), which can be cast as a semidefinite programme, that has been presented previously by Regula et al. [Phys. Rev. Lett. 121, 010401 (2018)]. Our results are given in terms of a smoothed min-relative entropy distance from the incoherent set of states, and a variant of the hypothesis-testing relative entropy distance, respectively. The one-shot distillable coherence is also related to one-shot randomness extraction. Moreover, from the one-shot formulas under IO, MIO, and DIO, we can recover the optimal distillable rate in the many-copy asymptotics, yielding the relative entropy of coherence. These results can be compared with previous work by some of the present authors [Zhao et al., Phys. Rev. Lett. 120, 070403 (2018)] on one-shot coherence formation under IO, MIO, DIO and also SIO. This shows that the amount of distillable coherence is essentially the same for IO, DIO, and MIO, despite the fact that the three classes of operations are very different. We also relate the distillable coherence under strictly incoherent operations (SIO) to a constrained hypothesis testing problem and explicitly show the existence of bound coherence under SIO in the asymptotic regime.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"vijayan-chitambar-hsieh-oneshotdistillationinageneralresourcetheory-2019\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  One-shot distillation in a general resource theory.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Vijayan,  M.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Hsieh,  M.\n</span>\n\n  \n\n</span>\n\n   2019.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/vijayan-chitambar-hsieh-oneshotdistillationinageneralresourcetheory-2019\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('vijayan-chitambar-hsieh-oneshotdistillationinageneralresourcetheory-2019')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@misc{\n title = {One-shot distillation in a general resource theory},\n type = {misc},\n year = {2019},\n source = {arXiv},\n id = {4489a828-41da-3770-a4a8-5350ff4f0dce},\n created = {2020-11-03T23:59:00.000Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-11-04T16:59:45.444Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Copyright © 2019, arXiv, All rights reserved. We present a general framework of a quantum resource theory based on the assumption of a) convexity and b) that the overlap of free states with maximally resourceful state is bounded. Using this structure, we derive bounds on the one-shot distillation rate for such a resource theory, thereby reproducing known bounds in coherence and entanglement. We use the free robustness and introduce a function Gmin(ρ) related to overlap between ρ and the set of free states to express our bounds. To deal with resource theories where the free robustness in not finite we introduce the notion of imperfect free operations which we call ϵ-resource generating operations and generalize the free robustness to ϵ-free robustness. We construct an ϵ-resource generating map that achieves pure state transformations in the theory and derive the conditions for such a transformation to exist in terms of the ϵ-free robustness.},\n bibtype = {misc},\n author = {Vijayan, M.K. and Chitambar, E. and Hsieh, M.-H.}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Copyright © 2019, arXiv, All rights reserved. We present a general framework of a quantum resource theory based on the assumption of a) convexity and b) that the overlap of free states with maximally resourceful state is bounded. Using this structure, we derive bounds on the one-shot distillation rate for such a resource theory, thereby reproducing known bounds in coherence and entanglement. We use the free robustness and introduce a function Gmin(ρ) related to overlap between ρ and the set of free states to express our bounds. To deal with resource theories where the free robustness in not finite we introduce the notion of imperfect free operations which we call ϵ-resource generating operations and generalize the free robustness to ϵ-free robustness. We construct an ϵ-resource generating map that achieves pure state transformations in the theory and derive the conditions for such a transformation to exist in terms of the ϵ-free robustness.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2018\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2018')\"\n      onkeypress=\"toggleGroup('group_2018')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2018</span>\n      <span class=\"bibbase_group_count\">\n        \n        (6)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"chitambar-dephasingcovariantoperationsenableasymptoticreversibilityofquantumresources-2018\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Dephasing-covariant operations enable asymptotic reversibility of quantum resources.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 97(5).  2018.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.97.050301\"\n     onclick=\"log_download('chitambar-dephasingcovariantoperationsenableasymptoticreversibilityofquantumresources-2018', 'http://doi.org/10.1103/PhysRevA.97.050301', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-dephasingcovariantoperationsenableasymptoticreversibilityofquantumresources-2018\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>2 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-dephasingcovariantoperationsenableasymptoticreversibilityofquantumresources-2018')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Dephasing-covariant operations enable asymptotic reversibility of quantum resources},\n type = {article},\n year = {2018},\n volume = {97},\n id = {151c3e2c-da77-395f-ae97-e6ad45abcd64},\n created = {2020-08-20T19:55:39.601Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.601Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2018 American Physical Society. We study the power of dephasing-covariant operations in the resource theories of coherence and entanglement. These are quantum operations whose actions commute with a projective measurement. In the resource theory of coherence, we find that any two states are asymptotically interconvertible under dephasing-covariant operations. This provides a rare example of a resource theory in which asymptotic reversibility can be attained without needing the maximal set of resource nongenerating operations. When extended to the resource theory of entanglement, the resultant operations share similarities with local operations and classical communication, such as prohibiting the increase of all Rényi α-entropies of entanglement under pure-state transformations. However, we show these operations are still strong enough to enable asymptotic reversibility between any two maximally correlated mixed states, even in the multipartite setting.},\n bibtype = {article},\n author = {Chitambar, E.},\n doi = {10.1103/PhysRevA.97.050301},\n journal = {Physical Review A},\n number = {5}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2018 American Physical Society. We study the power of dephasing-covariant operations in the resource theories of coherence and entanglement. These are quantum operations whose actions commute with a projective measurement. In the resource theory of coherence, we find that any two states are asymptotically interconvertible under dephasing-covariant operations. This provides a rare example of a resource theory in which asymptotic reversibility can be attained without needing the maximal set of resource nongenerating operations. When extended to the resource theory of entanglement, the resultant operations share similarities with local operations and classical communication, such as prohibiting the increase of all Rényi α-entropies of entanglement under pure-state transformations. However, we show these operations are still strong enough to enable asymptotic reversibility between any two maximally correlated mixed states, even in the multipartite setting.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"takahashi-chitambar-comparingcoherenceandentanglementunderresourcenongeneratingunitarytransformations-2018\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Comparing coherence and entanglement under resource non-generating unitary transformations.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Takahashi,  M.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Journal of Physics A: Mathematical and Theoretical</i>, 51(41).  2018.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1088/1751-8121/aacc5c\"\n     onclick=\"log_download('takahashi-chitambar-comparingcoherenceandentanglementunderresourcenongeneratingunitarytransformations-2018', 'http://doi.org/10.1088/1751-8121/aacc5c', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/takahashi-chitambar-comparingcoherenceandentanglementunderresourcenongeneratingunitarytransformations-2018\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('takahashi-chitambar-comparingcoherenceandentanglementunderresourcenongeneratingunitarytransformations-2018')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Comparing coherence and entanglement under resource non-generating unitary transformations},\n type = {article},\n year = {2018},\n keywords = {cohering power,quantum coherence,quantum entanglement,quantum information},\n volume = {51},\n id = {f7bb0eaf-f4d5-3f1e-a28b-09e0911ac99d},\n created = {2020-08-20T19:55:39.720Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.720Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2018 IOP Publishing Ltd. Quantum coherence is a fundamental property of quantum systems that can be studied within the framework of a quantum resource theory. From this resource-theoretic approach, many similarities emerge between coherence and quantum entanglement, the latter being another prominent quantum resource. In this paper, we study the relationship between coherence and entanglement from the perspective of resource loss/gain by unitary dynamics. Specifically we consider how much coherence can be either generated or destroyed on a bipartite system when the action is restricted to local unitary (LU) operations. For pure states, we find that the relative entropy of entanglement and the robustness of entanglement provide tight lower bounds on the amount of coherence that can be destroyed by LUs, as measured by the relative entropy and measures of coherence, respectively. This provides new operational interpretations of the entanglement entropy and robustness of entanglement in pure states as the minimal amount of coherence that persists when the system is subjected to LU transformations. We then study the amount of bipartite pure entanglement that can be either maximized or minimized when the action is restricted to a global incoherent operation. For two-qubit pure states, maximum and minimum are shown in terms of coefficients of given state with incoherent basis. Finally we consider a generalized version of the recently introduced CCP of a quantum channel.},\n bibtype = {article},\n author = {Takahashi, M. and Chitambar, E.},\n doi = {10.1088/1751-8121/aacc5c},\n journal = {Journal of Physics A: Mathematical and Theoretical},\n number = {41}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2018 IOP Publishing Ltd. Quantum coherence is a fundamental property of quantum systems that can be studied within the framework of a quantum resource theory. From this resource-theoretic approach, many similarities emerge between coherence and quantum entanglement, the latter being another prominent quantum resource. In this paper, we study the relationship between coherence and entanglement from the perspective of resource loss/gain by unitary dynamics. Specifically we consider how much coherence can be either generated or destroyed on a bipartite system when the action is restricted to local unitary (LU) operations. For pure states, we find that the relative entropy of entanglement and the robustness of entanglement provide tight lower bounds on the amount of coherence that can be destroyed by LUs, as measured by the relative entropy and measures of coherence, respectively. This provides new operational interpretations of the entanglement entropy and robustness of entanglement in pure states as the minimal amount of coherence that persists when the system is subjected to LU transformations. We then study the amount of bipartite pure entanglement that can be either maximized or minimized when the action is restricted to a global incoherent operation. For two-qubit pure states, maximum and minimum are shown in terms of coefficients of given state with incoherent basis. Finally we consider a generalized version of the recently introduced CCP of a quantum channel.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"dilley-chitambar-morenonlocalitywithlessentanglementinclauserhorneshimonyholtexperimentsusinginefficientdetectors-2018\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  More nonlocality with less entanglement in Clauser-Horne-Shimony-Holt experiments using inefficient detectors.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Dilley,  D.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 97(6).  2018.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.97.062313\"\n     onclick=\"log_download('dilley-chitambar-morenonlocalitywithlessentanglementinclauserhorneshimonyholtexperimentsusinginefficientdetectors-2018', 'http://doi.org/10.1103/PhysRevA.97.062313', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/dilley-chitambar-morenonlocalitywithlessentanglementinclauserhorneshimonyholtexperimentsusinginefficientdetectors-2018\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>1 download</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('dilley-chitambar-morenonlocalitywithlessentanglementinclauserhorneshimonyholtexperimentsusinginefficientdetectors-2018')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {More nonlocality with less entanglement in Clauser-Horne-Shimony-Holt experiments using inefficient detectors},\n type = {article},\n year = {2018},\n volume = {97},\n id = {9f896e13-50f7-3da3-9e13-06a686ccbcc6},\n created = {2020-08-20T19:55:39.738Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.738Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2018 American Physical Society. It is well-known that in certain scenarios weakly entangled states can generate stronger nonlocal effects than their maximally entangled counterparts. In this paper, we consider violations of the Clauser-Horne-Shimony-Holt (CHSH) inequality when one party has inefficient detectors, a scenario known as an asymmetric Bell experiment. For any fixed detection efficiency, we derive a simple upper bound on the entanglement needed to violate the inequality by more than some specified amount κ≥0. When κ=0, the amount of entanglement in all states violating the inequality goes to zero as the detection efficiency approaches 50% from above. We finally consider the scenario in which detection inefficiency arises for only one choice of local measurement. In this case, it is shown that the CHSH inequality can always be violated for any nonzero detection efficiency and any choice of noncommuting measurements.},\n bibtype = {article},\n author = {Dilley, D. and Chitambar, E.},\n doi = {10.1103/PhysRevA.97.062313},\n journal = {Physical Review A},\n number = {6}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2018 American Physical Society. It is well-known that in certain scenarios weakly entangled states can generate stronger nonlocal effects than their maximally entangled counterparts. In this paper, we consider violations of the Clauser-Horne-Shimony-Holt (CHSH) inequality when one party has inefficient detectors, a scenario known as an asymmetric Bell experiment. For any fixed detection efficiency, we derive a simple upper bound on the entanglement needed to violate the inequality by more than some specified amount κ≥0. When κ=0, the amount of entanglement in all states violating the inequality goes to zero as the detection efficiency approaches 50% from above. We finally consider the scenario in which detection inefficiency arises for only one choice of local measurement. In this case, it is shown that the CHSH inequality can always be violated for any nonzero detection efficiency and any choice of noncommuting measurements.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"vijayan-chitambar-hsieh-oneshotassistedconcentrationofcoherence-2018\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  One-shot assisted concentration of coherence.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Vijayan,  M.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Hsieh,  M.\n</span>\n\n  \n\n</span>\n\n  <i>Journal of Physics A: Mathematical and Theoretical</i>, 51(41).  2018.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1088/1751-8121/aadc21\"\n     onclick=\"log_download('vijayan-chitambar-hsieh-oneshotassistedconcentrationofcoherence-2018', 'http://doi.org/10.1088/1751-8121/aadc21', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/vijayan-chitambar-hsieh-oneshotassistedconcentrationofcoherence-2018\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>1 download</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('vijayan-chitambar-hsieh-oneshotassistedconcentrationofcoherence-2018')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {One-shot assisted concentration of coherence},\n type = {article},\n year = {2018},\n keywords = {assisted concentration of coherence,quantum coherence,quantum information},\n volume = {51},\n id = {079b5cfa-bee5-32b7-93fd-b84a875d3e98},\n created = {2020-08-20T19:55:40.010Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.010Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2018 IOP Publishing Ltd. We find one-shot bounds for concentration of maximally coherent states in the so called assisted scenario. In this setting, Bob is restricted to performing incoherent operations on his quantum system, however he is assisted by Alice, who holds a purification of Bob&#x27;s state and can send classical data to him. We further show that in the asymptotic limit our one-shot bounds recover the previously computed rate of asymptotic assisted concentration.},\n bibtype = {article},\n author = {Vijayan, M.K. and Chitambar, E. and Hsieh, M.-H.},\n doi = {10.1088/1751-8121/aadc21},\n journal = {Journal of Physics A: Mathematical and Theoretical},\n number = {41}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2018 IOP Publishing Ltd. We find one-shot bounds for concentration of maximally coherent states in the so called assisted scenario. In this setting, Bob is restricted to performing incoherent operations on his quantum system, however he is assisted by Alice, who holds a purification of Bob's state and can send classical data to him. We further show that in the asymptotic limit our one-shot bounds recover the previously computed rate of asymptotic assisted concentration.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-fortescue-hsieh-theconditionalcommoninformationinclassicalandquantumsecretkeydistillation-2018\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  The Conditional Common Information in Classical and Quantum Secret Key Distillation.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Fortescue,  B.;  and Hsieh,  M.\n</span>\n\n  \n\n</span>\n\n  <i>IEEE Transactions on Information Theory</i>, 64(11).  2018.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1109/TIT.2018.2851564\"\n     onclick=\"log_download('chitambar-fortescue-hsieh-theconditionalcommoninformationinclassicalandquantumsecretkeydistillation-2018', 'http://doi.org/10.1109/TIT.2018.2851564', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-fortescue-hsieh-theconditionalcommoninformationinclassicalandquantumsecretkeydistillation-2018\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>1 download</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-fortescue-hsieh-theconditionalcommoninformationinclassicalandquantumsecretkeydistillation-2018')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {The Conditional Common Information in Classical and Quantum Secret Key Distillation},\n type = {article},\n year = {2018},\n keywords = {Quantum cryptography,common information,quantum information,secret key distillation},\n volume = {64},\n id = {4afb2101-5389-3b82-96e6-109eb342fb4a},\n created = {2020-08-20T19:55:40.028Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.028Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2018 IEEE. In this paper, we consider two extensions of the Gács-Körner common information to three variables, the conditional common information (cCI) and the coarse-grained conditional common information (ccCI). Both quantities are shown to be useful technical tools in the study of classical and quantum resource transformations. In particular, the ccCI is shown to have an operational interpretation as the optimal rate of secret key extraction from an eavesdropped classical source pXYZ when Alice (X) and Bob (Y) are unable to communicate but share common randomness with the eavesdropper Eve (Z). Moving to the quantum setting, we consider two different ways of generating a tripartite quantum state from classical correlations pXYZ : 1) coherent encodings ∑xyz√pxyz|xyz〉 and 2) incoherent encodings ∑xyzpxyz|xyz〉〈xyz|. We study how well can Alice and Bob extract secret key from these quantum sources using quantum operations compared with the extraction of key from the underlying classical sources pXYZ using classical operations. While the power of quantum mechanics increases Alice and Bob&#x27;s ability to generate shared randomness, it also equips Eve with a greater arsenal of eavesdropping attacks. Therefore, it is not obvious who gains the greatest advantage for distilling secret key when replacing a classical source with a quantum one. We first demonstrate that the classical key rate of pXYZ is equivalent to the quantum key rate for an incoherent quantum encoding of the distribution. For coherent encodings, we next show that the classical and quantum rates are generally incomparable, and in fact, their difference can be arbitrarily large in either direction. Finally, we introduce a &quot;zoo&quot; of entangled tripartite states all characterized by the conditional common information of their encoded probability distributions. Remarkably, for these states almost all entanglement measures, such as Alice and Bob&#x27;s entanglement cost, squashed entanglement, and relative entropy of entanglement, can be sharply bounded or even exactly expressed in terms of the conditional common information. In the latter case, we thus present a rare instance in which the various entropic entanglement measures of a quantum state can be explicitly calculated.},\n bibtype = {article},\n author = {Chitambar, E. and Fortescue, B. and Hsieh, M.-H.},\n doi = {10.1109/TIT.2018.2851564},\n journal = {IEEE Transactions on Information Theory},\n number = {11}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2018 IEEE. In this paper, we consider two extensions of the Gács-Körner common information to three variables, the conditional common information (cCI) and the coarse-grained conditional common information (ccCI). Both quantities are shown to be useful technical tools in the study of classical and quantum resource transformations. In particular, the ccCI is shown to have an operational interpretation as the optimal rate of secret key extraction from an eavesdropped classical source pXYZ when Alice (X) and Bob (Y) are unable to communicate but share common randomness with the eavesdropper Eve (Z). Moving to the quantum setting, we consider two different ways of generating a tripartite quantum state from classical correlations pXYZ : 1) coherent encodings ∑xyz√pxyz|xyz〉 and 2) incoherent encodings ∑xyzpxyz|xyz〉〈xyz|. We study how well can Alice and Bob extract secret key from these quantum sources using quantum operations compared with the extraction of key from the underlying classical sources pXYZ using classical operations. While the power of quantum mechanics increases Alice and Bob's ability to generate shared randomness, it also equips Eve with a greater arsenal of eavesdropping attacks. Therefore, it is not obvious who gains the greatest advantage for distilling secret key when replacing a classical source with a quantum one. We first demonstrate that the classical key rate of pXYZ is equivalent to the quantum key rate for an incoherent quantum encoding of the distribution. For coherent encodings, we next show that the classical and quantum rates are generally incomparable, and in fact, their difference can be arbitrarily large in either direction. Finally, we introduce a \"zoo\" of entangled tripartite states all characterized by the conditional common information of their encoded probability distributions. Remarkably, for these states almost all entanglement measures, such as Alice and Bob's entanglement cost, squashed entanglement, and relative entropy of entanglement, can be sharply bounded or even exactly expressed in terms of the conditional common information. In the latter case, we thus present a rare instance in which the various entropic entanglement measures of a quantum state can be explicitly calculated.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"zhao-liu-yuan-chitambar-ma-oneshotcoherencedilution-2018\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  One-Shot Coherence Dilution.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Zhao,  Q.; Liu,  Y.; Yuan,  X.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Ma,  X.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 120(7).  2018.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.120.070403\"\n     onclick=\"log_download('zhao-liu-yuan-chitambar-ma-oneshotcoherencedilution-2018', 'http://doi.org/10.1103/PhysRevLett.120.070403', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/zhao-liu-yuan-chitambar-ma-oneshotcoherencedilution-2018\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>2 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('zhao-liu-yuan-chitambar-ma-oneshotcoherencedilution-2018')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {One-Shot Coherence Dilution},\n type = {article},\n year = {2018},\n volume = {120},\n id = {098aadac-771d-306d-99af-fd57ec84d625},\n created = {2020-08-20T19:55:40.516Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.516Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2018 American Physical Society. Manipulation and quantification of quantum resources are fundamental problems in quantum physics. In the asymptotic limit, coherence distillation and dilution have been proposed by manipulating infinite identical copies of states. In the nonasymptotic setting, finite data-size effects emerge, and the practically relevant problem of coherence manipulation using finite resources has been left open. This Letter establishes the one-shot theory of coherence dilution, which involves converting maximally coherent states into an arbitrary quantum state using maximally incoherent operations, dephasing-covariant incoherent operations, incoherent operations, or strictly incoherent operations. We introduce several coherence monotones with concrete operational interpretations that estimate the one-shot coherence cost - the minimum amount of maximally coherent states needed for faithful coherence dilution. Furthermore, we derive the asymptotic coherence dilution results with maximally incoherent operations, incoherent operations, and strictly incoherent operations as special cases. Our result can be applied in the analyses of quantum information processing tasks that exploit coherence as resources, such as quantum key distribution and random number generation.},\n bibtype = {article},\n author = {Zhao, Q. and Liu, Y. and Yuan, X. and Chitambar, E. and Ma, X.},\n doi = {10.1103/PhysRevLett.120.070403},\n journal = {Physical Review Letters},\n number = {7}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2018 American Physical Society. Manipulation and quantification of quantum resources are fundamental problems in quantum physics. In the asymptotic limit, coherence distillation and dilution have been proposed by manipulating infinite identical copies of states. In the nonasymptotic setting, finite data-size effects emerge, and the practically relevant problem of coherence manipulation using finite resources has been left open. This Letter establishes the one-shot theory of coherence dilution, which involves converting maximally coherent states into an arbitrary quantum state using maximally incoherent operations, dephasing-covariant incoherent operations, incoherent operations, or strictly incoherent operations. We introduce several coherence monotones with concrete operational interpretations that estimate the one-shot coherence cost - the minimum amount of maximally coherent states needed for faithful coherence dilution. Furthermore, we derive the asymptotic coherence dilution results with maximally incoherent operations, incoherent operations, and strictly incoherent operations as special cases. Our result can be applied in the analyses of quantum information processing tasks that exploit coherence as resources, such as quantum key distribution and random number generation.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2017\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2017')\"\n      onkeypress=\"toggleGroup('group_2017')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2017</span>\n      <span class=\"bibbase_group_count\">\n        \n        (4)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"chitambar-hsieh-roundcomplexityinthelocaltransformationsofquantumandclassicalstates-2017\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Round complexity in the local transformations of quantum and classical states.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Hsieh,  M.\n</span>\n\n  \n\n</span>\n\n  <i>Nature Communications</i>, 8(1).  2017.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1038/s41467-017-01887-5\"\n     onclick=\"log_download('chitambar-hsieh-roundcomplexityinthelocaltransformationsofquantumandclassicalstates-2017', 'http://doi.org/10.1038/s41467-017-01887-5', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-hsieh-roundcomplexityinthelocaltransformationsofquantumandclassicalstates-2017\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>2 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-hsieh-roundcomplexityinthelocaltransformationsofquantumandclassicalstates-2017')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Round complexity in the local transformations of quantum and classical states},\n type = {article},\n year = {2017},\n volume = {8},\n id = {33eb12e6-a036-3823-afbc-f9af47594bcc},\n created = {2020-08-20T19:55:39.761Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.761Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2017 The Author(s). In distributed quantum and classical information processing, spatially separated parties operate locally on their respective subsystems, but coordinate their actions through multiple exchanges of public communication. With interaction, the parties can perform more tasks. But how the exact number and order of exchanges enhances their operational capabilities is not well understood. Here we consider the minimum number of communication rounds needed to perform the locality-constrained tasks of entanglement transformation and its classical analog of secrecy manipulation. We provide an explicit construction of both quantum and classical state transformations which, for any given r, can be achieved using r rounds of classical communication exchanges, but no fewer. To show this, we build on the common structure underlying both resource theories of quantum entanglement and classical secret key. Our results reveal that highly complex communication protocols are indeed necessary to fully harness the information-theoretic resources contained in general quantum and classical states.},\n bibtype = {article},\n author = {Chitambar, E. and Hsieh, M.-H.},\n doi = {10.1038/s41467-017-01887-5},\n journal = {Nature Communications},\n number = {1}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2017 The Author(s). In distributed quantum and classical information processing, spatially separated parties operate locally on their respective subsystems, but coordinate their actions through multiple exchanges of public communication. With interaction, the parties can perform more tasks. But how the exact number and order of exchanges enhances their operational capabilities is not well understood. Here we consider the minimum number of communication rounds needed to perform the locality-constrained tasks of entanglement transformation and its classical analog of secrecy manipulation. We provide an explicit construction of both quantum and classical state transformations which, for any given r, can be achieved using r rounds of classical communication exchanges, but no fewer. To show this, we build on the common structure underlying both resource theories of quantum entanglement and classical secret key. Our results reveal that highly complex communication protocols are indeed necessary to fully harness the information-theoretic resources contained in general quantum and classical states.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"zhao-liu-yuan-chitambar-ma-oneshotcoherencedilution-2017\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  One-shot coherence dilution.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Zhao,  Q.; Liu,  Y.; Yuan,  X.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Ma,  X.\n</span>\n\n  \n\n</span>\n\n   2017.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/zhao-liu-yuan-chitambar-ma-oneshotcoherencedilution-2017\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('zhao-liu-yuan-chitambar-ma-oneshotcoherencedilution-2017')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@misc{\n title = {One-shot coherence dilution},\n type = {misc},\n year = {2017},\n source = {arXiv},\n id = {6fc95380-ce40-3e52-8c7e-d900dcbf9d05},\n created = {2020-10-27T23:59:00.000Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-10-30T08:41:11.297Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Copyright © 2017, arXiv, All rights reserved. Manipulation and quantification of quantum resources are fundamental problems in quantum physics. In the asymptotic limit, coherence distillation and dilution have been proposed by manipulating infinite identical copies of states. In the nonasymptotic setting, finite data-size effects emerge, and the practically relevant problem of coherence manipulation using finite resources has been left open. This Letter establishes the one-shot theory of coherence dilution, which involves converting maximally coherent states into an arbitrary quantum state using maximally incoherent operations, dephasing-covariant incoherent operations, incoherent operations, or strictly incoherent operations. We introduce several coherence monotones with concrete operational interpretations that estimate the one-shot coherence cost-the minimum amount of maximally coherent states needed for faithful coherence dilution. Furthermore, we derive the asymptotic coherence dilution results with maximally incoherent operations, incoherent operations, and strictly incoherent operations as special cases. Our result can be applied in the analyses of quantum information processing tasks that exploit coherence as resources, such as quantum key distribution and random number generation.},\n bibtype = {misc},\n author = {Zhao, Q. and Liu, Y. and Yuan, X. and Chitambar, E. and Ma, X.}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Copyright © 2017, arXiv, All rights reserved. Manipulation and quantification of quantum resources are fundamental problems in quantum physics. In the asymptotic limit, coherence distillation and dilution have been proposed by manipulating infinite identical copies of states. In the nonasymptotic setting, finite data-size effects emerge, and the practically relevant problem of coherence manipulation using finite resources has been left open. This Letter establishes the one-shot theory of coherence dilution, which involves converting maximally coherent states into an arbitrary quantum state using maximally incoherent operations, dephasing-covariant incoherent operations, incoherent operations, or strictly incoherent operations. We introduce several coherence monotones with concrete operational interpretations that estimate the one-shot coherence cost-the minimum amount of maximally coherent states needed for faithful coherence dilution. Furthermore, we derive the asymptotic coherence dilution results with maximally incoherent operations, incoherent operations, and strictly incoherent operations as special cases. Our result can be applied in the analyses of quantum information processing tasks that exploit coherence as resources, such as quantum key distribution and random number generation.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-devicente-girard-gour-entanglementmanipulationanddistillabilitybeyondlocc-2017\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Entanglement manipulation and distillability beyond LOCC.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; De Vicente,  J.; Girard,  M.;  and Gour,  G.\n</span>\n\n  \n\n</span>\n\n   2017.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-devicente-girard-gour-entanglementmanipulationanddistillabilitybeyondlocc-2017\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-devicente-girard-gour-entanglementmanipulationanddistillabilitybeyondlocc-2017')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@misc{\n title = {Entanglement manipulation and distillability beyond LOCC},\n type = {misc},\n year = {2017},\n source = {arXiv},\n id = {a3a4a68b-b654-38c2-9bc7-c197ffe03a00},\n created = {2020-10-27T23:59:00.000Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-10-31T01:16:47.915Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Copyright © 2017, arXiv, All rights reserved. When a quantum system is distributed to spatially separated parties, it is natural to consider how the system evolves when the parties perform local quantum operations with classical communication (LOCC). However, the structure of LOCC channels is exceedingly complex leaving many important physical problems unsolved. In this paper we consider generalized resource theories of entanglement based on different relaxations to the class of LOCC. The behavior of various entanglement measures is studied under non-entangling channels, as well as the newly introduced classes of dually non-entangling and PPT-preserving channels. In an effort to better understand the nature of LOCC bound entanglement, we study the problem of entanglement distillation in these generalized resource theories. We first show that unlike LOCC, general non-entangling maps can be superactivated, in the sense that two copies of the same non-entangling map can nevertheless be entangling. On the single-copy level, we demonstrate that every NPT entangled state can be converted into an LOCC-distillable state using channels that are both dually non-entangling and having a PPT Choi representation and that every state can be converted into an LOCC-distillable state using operations belonging to any family of polytopes that approximate LOCC. We then turn to the stochastic convertibility of multipartite pure states and show that any two states can be interconverted by any polytope approximation to the set of separable channels. Finally, as an analog to k-positive maps, we introduce and analyze the set of k-non-entangling channels.},\n bibtype = {misc},\n author = {Chitambar, E. and De Vicente, J.I. and Girard, M.W. and Gour, G.}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Copyright © 2017, arXiv, All rights reserved. When a quantum system is distributed to spatially separated parties, it is natural to consider how the system evolves when the parties perform local quantum operations with classical communication (LOCC). However, the structure of LOCC channels is exceedingly complex leaving many important physical problems unsolved. In this paper we consider generalized resource theories of entanglement based on different relaxations to the class of LOCC. The behavior of various entanglement measures is studied under non-entangling channels, as well as the newly introduced classes of dually non-entangling and PPT-preserving channels. In an effort to better understand the nature of LOCC bound entanglement, we study the problem of entanglement distillation in these generalized resource theories. We first show that unlike LOCC, general non-entangling maps can be superactivated, in the sense that two copies of the same non-entangling map can nevertheless be entangling. On the single-copy level, we demonstrate that every NPT entangled state can be converted into an LOCC-distillable state using channels that are both dually non-entangling and having a PPT Choi representation and that every state can be converted into an LOCC-distillable state using operations belonging to any family of polytopes that approximate LOCC. We then turn to the stochastic convertibility of multipartite pure states and show that any two states can be interconverted by any polytope approximation to the set of separable channels. Finally, as an analog to k-positive maps, we introduce and analyze the set of k-non-entangling channels.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-dephasingcovariantoperationsenableasymptoticreversibilityofquantumresources-2017\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Dephasing-Covariant Operations Enable Asymptotic Reversibility of Quantum Resources.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n   2017.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-dephasingcovariantoperationsenableasymptoticreversibilityofquantumresources-2017\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-dephasingcovariantoperationsenableasymptoticreversibilityofquantumresources-2017')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@misc{\n title = {Dephasing-Covariant Operations Enable Asymptotic Reversibility of Quantum Resources},\n type = {misc},\n year = {2017},\n source = {arXiv},\n id = {8ac819e4-af60-31cb-b05e-a9d21cb78dce},\n created = {2020-11-03T23:59:00.000Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-11-05T01:35:55.742Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Copyright © 2017, arXiv, All rights reserved. We study the power of dephasing-covariant operations in the resource theories of coherence and entanglement. These are quantum operations whose actions commute with a projective measurement. In the resource theory of coherence, we find that any two states are asymptotically interconvertible under dephasing-covariant operations. This provides a rare example of a resource theory in which asymptotic reversibility can be attained without needing the maximal set of resource non-generating operations. When extended to the resource theory of entanglement, the resultant operations share similarities with LOCC, such as prohibiting the increase of all Rényi α-entropies of entanglement under pure state transformations. However, we show these operations are still strong enough to enable asymptotic reversibility between any two maximally correlated mixed states, even in the multipartite setting.},\n bibtype = {misc},\n author = {Chitambar, E.}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Copyright © 2017, arXiv, All rights reserved. We study the power of dephasing-covariant operations in the resource theories of coherence and entanglement. These are quantum operations whose actions commute with a projective measurement. In the resource theory of coherence, we find that any two states are asymptotically interconvertible under dephasing-covariant operations. This provides a rare example of a resource theory in which asymptotic reversibility can be attained without needing the maximal set of resource non-generating operations. When extended to the resource theory of entanglement, the resultant operations share similarities with LOCC, such as prohibiting the increase of all Rényi α-entropies of entanglement under pure state transformations. However, we show these operations are still strong enough to enable asymptotic reversibility between any two maximally correlated mixed states, even in the multipartite setting.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2016\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2016')\"\n      onkeypress=\"toggleGroup('group_2016')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2016</span>\n      <span class=\"bibbase_group_count\">\n        \n        (9)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"chitambar-gour-comparisonofincoherentoperationsandmeasuresofcoherence-2016\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Comparison of incoherent operations and measures of coherence.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Gour,  G.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 94(5).  2016.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.94.052336\"\n     onclick=\"log_download('chitambar-gour-comparisonofincoherentoperationsandmeasuresofcoherence-2016', 'http://doi.org/10.1103/PhysRevA.94.052336', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-gour-comparisonofincoherentoperationsandmeasuresofcoherence-2016\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-gour-comparisonofincoherentoperationsandmeasuresofcoherence-2016')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Comparison of incoherent operations and measures of coherence},\n type = {article},\n year = {2016},\n volume = {94},\n id = {4a0d2efa-8608-36a8-bbe3-55558cb82f54},\n created = {2020-08-20T19:55:39.782Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.782Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2016 American Physical Society. A resource theory of quantum coherence attempts to characterize the quantum coherence that exists in a given quantum system. Many different approaches to a resource theory of coherence have recently been proposed, with their differences lying primarily in the identification of &quot;free&quot; or &quot;incoherent&quot; operations. In this article, we compare a number of these operational classes. In particular, the recently introduced class of dephasing-covariant operations is analyzed, and we characterize the Kraus operators of such maps. A number of coherence measures are introduced based on relative Rényi entropies, and we study incoherent state transformations under different operational classes. In particular, we show that the incoherent Schmidt rank can be increased arbitrarily large by certain noncoherence generating operations. The distinction between asymmetry-based versus basis-dependent notions of coherence theory is clarified, and we further develop the resource theory of N asymmetry, where N is the group of all diagonal incoherent unitaries.},\n bibtype = {article},\n author = {Chitambar, E. and Gour, G.},\n doi = {10.1103/PhysRevA.94.052336},\n journal = {Physical Review A},\n number = {5}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2016 American Physical Society. A resource theory of quantum coherence attempts to characterize the quantum coherence that exists in a given quantum system. Many different approaches to a resource theory of coherence have recently been proposed, with their differences lying primarily in the identification of \"free\" or \"incoherent\" operations. In this article, we compare a number of these operational classes. In particular, the recently introduced class of dephasing-covariant operations is analyzed, and we characterize the Kraus operators of such maps. A number of coherence measures are introduced based on relative Rényi entropies, and we study incoherent state transformations under different operational classes. In particular, we show that the incoherent Schmidt rank can be increased arbitrarily large by certain noncoherence generating operations. The distinction between asymmetry-based versus basis-dependent notions of coherence theory is clarified, and we further develop the resource theory of N asymmetry, where N is the group of all diagonal incoherent unitaries.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-gour-criticalexaminationofincoherentoperationsandaphysicallyconsistentresourcetheoryofquantumcoherence-2016\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Critical Examination of Incoherent Operations and a Physically Consistent Resource Theory of Quantum Coherence.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Gour,  G.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 117(3).  2016.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.117.030401\"\n     onclick=\"log_download('chitambar-gour-criticalexaminationofincoherentoperationsandaphysicallyconsistentresourcetheoryofquantumcoherence-2016', 'http://doi.org/10.1103/PhysRevLett.117.030401', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-gour-criticalexaminationofincoherentoperationsandaphysicallyconsistentresourcetheoryofquantumcoherence-2016\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-gour-criticalexaminationofincoherentoperationsandaphysicallyconsistentresourcetheoryofquantumcoherence-2016')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Critical Examination of Incoherent Operations and a Physically Consistent Resource Theory of Quantum Coherence},\n type = {article},\n year = {2016},\n volume = {117},\n id = {8613c0c1-11a3-3e12-8d45-a4a2242ed25f},\n created = {2020-08-20T19:55:39.805Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.805Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2016 American Physical Society. Considerable work has recently been directed toward developing resource theories of quantum coherence. In this Letter, we establish a criterion of physical consistency for any resource theory. This criterion requires that all free operations in a given resource theory be implementable by a unitary evolution and projective measurement that are both free operations in an extended resource theory. We show that all currently proposed basis-dependent theories of coherence fail to satisfy this criterion. We further characterize the physically consistent resource theory of coherence and find its operational power to be quite limited. After relaxing the condition of physical consistency, we introduce the class of dephasing-covariant incoherent operations as a natural generalization of the physically consistent operations. Necessary and sufficient conditions are derived for the convertibility of qubit states using dephasing-covariant operations, and we show that these conditions also hold for other well-known classes of incoherent operations.},\n bibtype = {article},\n author = {Chitambar, E. and Gour, G.},\n doi = {10.1103/PhysRevLett.117.030401},\n journal = {Physical Review Letters},\n number = {3}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2016 American Physical Society. Considerable work has recently been directed toward developing resource theories of quantum coherence. In this Letter, we establish a criterion of physical consistency for any resource theory. This criterion requires that all free operations in a given resource theory be implementable by a unitary evolution and projective measurement that are both free operations in an extended resource theory. We show that all currently proposed basis-dependent theories of coherence fail to satisfy this criterion. We further characterize the physically consistent resource theory of coherence and find its operational power to be quite limited. After relaxing the condition of physical consistency, we introduce the class of dephasing-covariant incoherent operations as a natural generalization of the physically consistent operations. Necessary and sufficient conditions are derived for the convertibility of qubit states using dephasing-covariant operations, and we show that these conditions also hold for other well-known classes of incoherent operations.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-hsieh-relatingtheresourcetheoriesofentanglementandquantumcoherence-2016\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Relating the Resource Theories of Entanglement and Quantum Coherence.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Hsieh,  M.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 117(2).  2016.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.117.020402\"\n     onclick=\"log_download('chitambar-hsieh-relatingtheresourcetheoriesofentanglementandquantumcoherence-2016', 'http://doi.org/10.1103/PhysRevLett.117.020402', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-hsieh-relatingtheresourcetheoriesofentanglementandquantumcoherence-2016\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>2 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-hsieh-relatingtheresourcetheoriesofentanglementandquantumcoherence-2016')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Relating the Resource Theories of Entanglement and Quantum Coherence},\n type = {article},\n year = {2016},\n volume = {117},\n id = {baf627f0-b9bb-392b-992f-c2d139e6b7e6},\n created = {2020-08-20T19:55:39.824Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.824Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2016 American Physical Society. Quantum coherence and quantum entanglement represent two fundamental features of nonclassical systems that can each be characterized within an operational resource theory. In this Letter, we unify the resource theories of entanglement and coherence by studying their combined behavior in the operational setting of local incoherent operations and classical communication (LIOCC). Specifically, we analyze the coherence and entanglement trade-offs in the tasks of state formation and resource distillation. For pure states we identify the minimum coherence-entanglement resources needed to generate a given state, and we introduce a new LIOCC monotone that completely characterizes a state&#x27;s optimal rate of bipartite coherence distillation. This result allows us to precisely quantify the difference in operational powers between global incoherent operations, LIOCC, and local incoherent operations without classical communication. Finally, a bipartite mixed state is shown to have distillable entanglement if and only if entanglement can be distilled by LIOCC, and we strengthen the well-known Horodecki criterion for distillability.},\n bibtype = {article},\n author = {Chitambar, E. and Hsieh, M.-H.},\n doi = {10.1103/PhysRevLett.117.020402},\n journal = {Physical Review Letters},\n number = {2}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2016 American Physical Society. Quantum coherence and quantum entanglement represent two fundamental features of nonclassical systems that can each be characterized within an operational resource theory. In this Letter, we unify the resource theories of entanglement and coherence by studying their combined behavior in the operational setting of local incoherent operations and classical communication (LIOCC). Specifically, we analyze the coherence and entanglement trade-offs in the tasks of state formation and resource distillation. For pure states we identify the minimum coherence-entanglement resources needed to generate a given state, and we introduce a new LIOCC monotone that completely characterizes a state's optimal rate of bipartite coherence distillation. This result allows us to precisely quantify the difference in operational powers between global incoherent operations, LIOCC, and local incoherent operations without classical communication. Finally, a bipartite mixed state is shown to have distillable entanglement if and only if entanglement can be distilled by LIOCC, and we strengthen the well-known Horodecki criterion for distillability.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"byrd-ceballos-chitambar-opensystemquantumevolutionandtheassumptionofcompletepositivityatutorial-2016\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Open system quantum evolution and the assumption of complete positivity (A Tutorial).\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Byrd,  M.; Ceballos,  R.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>International Journal of Quantum Information</i>, 14(6).  2016.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1142/S0219749916400232\"\n     onclick=\"log_download('byrd-ceballos-chitambar-opensystemquantumevolutionandtheassumptionofcompletepositivityatutorial-2016', 'http://doi.org/10.1142/S0219749916400232', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/byrd-ceballos-chitambar-opensystemquantumevolutionandtheassumptionofcompletepositivityatutorial-2016\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('byrd-ceballos-chitambar-opensystemquantumevolutionandtheassumptionofcompletepositivityatutorial-2016')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Open system quantum evolution and the assumption of complete positivity (A Tutorial)},\n type = {article},\n year = {2016},\n keywords = {Open quantum systems,dynamical maps,positive maps},\n volume = {14},\n id = {0e3bd8e9-092c-3e48-a9c5-fc92052e53b3},\n created = {2020-08-20T19:55:40.049Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.049Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2016 World Scientific Publishing Company. Quantum systems which interact with an unknown environment cannot be described in terms of a unitary evolution on the system alone. For such evolution one can use a map from one density operator to another and use any other known information to model the system. Such maps are required to be positive (at least on their domain) - they take positive density operators to positive density operators - so as to be physically reasonable. A map Φ which is positive but not completely positive (CP) is one which takes positive operators to positive operators, but when extended by the identity In, i.e. In In⊗ Φ does not give a positive map for some In. The map is CP if and only if the extension is positive for all n. Recently some effort has been put forth to try to understand if, and/or, under what circumstances one might utilize a non-CP map. Here, after a tutorial-type introduction to maps from one density operator to another, some examples which do not fit the standard prescription (SP) for deriving a CP map are given. In cases where the physical system is constrained by some knowledge of the interaction, it is possible that the SP cannot be used directly. Our example is robust to changes in the initial and final conditions.},\n bibtype = {article},\n author = {Byrd, M. and Ceballos, R. and Chitambar, E.},\n doi = {10.1142/S0219749916400232},\n journal = {International Journal of Quantum Information},\n number = {6}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2016 World Scientific Publishing Company. Quantum systems which interact with an unknown environment cannot be described in terms of a unitary evolution on the system alone. For such evolution one can use a map from one density operator to another and use any other known information to model the system. Such maps are required to be positive (at least on their domain) - they take positive density operators to positive density operators - so as to be physically reasonable. A map Φ which is positive but not completely positive (CP) is one which takes positive operators to positive operators, but when extended by the identity In, i.e. In In⊗ Φ does not give a positive map for some In. The map is CP if and only if the extension is positive for all n. Recently some effort has been put forth to try to understand if, and/or, under what circumstances one might utilize a non-CP map. Here, after a tutorial-type introduction to maps from one density operator to another, some examples which do not fit the standard prescription (SP) for deriving a CP map are given. In cases where the physical system is constrained by some knowledge of the interaction, it is possible that the SP cannot be used directly. Our example is robust to changes in the initial and final conditions.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-hsieh-winter-theprivateandpubliccorrelationcostofthreerandomvariableswithcollaboration-2016\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  The private and public correlation cost of three random variables with collaboration.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Hsieh,  M.;  and Winter,  A.\n</span>\n\n  \n\n</span>\n\n  <i>IEEE Transactions on Information Theory</i>, 62(4).  2016.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1109/TIT.2016.2530086\"\n     onclick=\"log_download('chitambar-hsieh-winter-theprivateandpubliccorrelationcostofthreerandomvariableswithcollaboration-2016', 'http://doi.org/10.1109/TIT.2016.2530086', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-hsieh-winter-theprivateandpubliccorrelationcostofthreerandomvariableswithcollaboration-2016\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-hsieh-winter-theprivateandpubliccorrelationcostofthreerandomvariableswithcollaboration-2016')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {The private and public correlation cost of three random variables with collaboration},\n type = {article},\n year = {2016},\n keywords = {Wyner common information,local operations and public communication,reverse shannon theorem,secret key cost},\n volume = {62},\n id = {13cefc10-8643-3c40-abc2-efddff4747c4},\n created = {2020-08-20T19:55:40.072Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.072Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2016 IEEE. In this paper, we consider the problem of generating arbitrary three-party correlations from a combination of public and secret correlations. Two parties - called Alice and Bob - share perfectly correlated bits that are secret from a collaborating third party, Charlie. At the same time, all three parties have access to a separate source of correlated bits, and their goal is to convert these two resources into multiple copies of some given tripartite distribution ℙ(XYZ). We obtain a single-letter characterization of the tradeoff between public and private bits that are needed to achieve this task. The rate of private bits is shown to generalize Wyner&#x27;s classic notion of common information held between a pair of random variables. The problem we consider can be contrasted fruitfully with the task of secrecy formation, in which ℙ(XYZ) is generated using public communication and local randomness but with Charlie functioning as an adversary instead of a collaborator. We describe in detail the differences between the collaborative and adversarial scenarios.},\n bibtype = {article},\n author = {Chitambar, E. and Hsieh, M.-H. and Winter, A.},\n doi = {10.1109/TIT.2016.2530086},\n journal = {IEEE Transactions on Information Theory},\n number = {4}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2016 IEEE. In this paper, we consider the problem of generating arbitrary three-party correlations from a combination of public and secret correlations. Two parties - called Alice and Bob - share perfectly correlated bits that are secret from a collaborating third party, Charlie. At the same time, all three parties have access to a separate source of correlated bits, and their goal is to convert these two resources into multiple copies of some given tripartite distribution ℙ(XYZ). We obtain a single-letter characterization of the tradeoff between public and private bits that are needed to achieve this task. The rate of private bits is shown to generalize Wyner's classic notion of common information held between a pair of random variables. The problem we consider can be contrasted fruitfully with the task of secrecy formation, in which ℙ(XYZ) is generated using public communication and local randomness but with Charlie functioning as an adversary instead of a collaborator. We describe in detail the differences between the collaborative and adversarial scenarios.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"lim-xu-siopsis-chitambar-evans-qi-losstolerantquantumsecurepositioningwithweaklasersources-2016\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Loss-tolerant quantum secure positioning with weak laser sources.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Lim,  C.; Xu,  F.; Siopsis,  G.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Evans,  P.;  and Qi,  B.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A</i>, 94(3).  2016.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.94.032315\"\n     onclick=\"log_download('lim-xu-siopsis-chitambar-evans-qi-losstolerantquantumsecurepositioningwithweaklasersources-2016', 'http://doi.org/10.1103/PhysRevA.94.032315', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/lim-xu-siopsis-chitambar-evans-qi-losstolerantquantumsecurepositioningwithweaklasersources-2016\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('lim-xu-siopsis-chitambar-evans-qi-losstolerantquantumsecurepositioningwithweaklasersources-2016')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Loss-tolerant quantum secure positioning with weak laser sources},\n type = {article},\n year = {2016},\n volume = {94},\n id = {3ec9537c-2c12-34c4-a600-3131eea4ffb4},\n created = {2020-08-20T19:55:40.601Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.601Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2016 American Physical Society. Quantum position verification (QPV) is the art of verifying the geographical location of an untrusted party. Recently, it has been shown that the widely studied Bennett &amp; Brassard 1984 (BB84) QPV protocol is insecure after the 3 dB loss point assuming local operations and classical communication (LOCC) adversaries. Here, we propose a time-reversed entanglement swapping QPV protocol (based on measurement-device-independent quantum cryptography) that is highly robust against quantum channel loss. First, assuming ideal qubit sources, we show that the protocol is secure against LOCC adversaries for any quantum channel loss, thereby overcoming the 3 dB loss limit. Then, we analyze the security of the protocol in a more practical setting involving weak laser sources and linear optics. In this setting, we find that the security only degrades by an additive constant and the protocol is able to verify positions up to 47 dB channel loss.},\n bibtype = {article},\n author = {Lim, C.C.W. and Xu, F. and Siopsis, G. and Chitambar, E. and Evans, P.G. and Qi, B.},\n doi = {10.1103/PhysRevA.94.032315},\n journal = {Physical Review A},\n number = {3}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2016 American Physical Society. Quantum position verification (QPV) is the art of verifying the geographical location of an untrusted party. Recently, it has been shown that the widely studied Bennett & Brassard 1984 (BB84) QPV protocol is insecure after the 3 dB loss point assuming local operations and classical communication (LOCC) adversaries. Here, we propose a time-reversed entanglement swapping QPV protocol (based on measurement-device-independent quantum cryptography) that is highly robust against quantum channel loss. First, assuming ideal qubit sources, we show that the protocol is secure against LOCC adversaries for any quantum channel loss, thereby overcoming the 3 dB loss limit. Then, we analyze the security of the protocol in a more practical setting involving weak laser sources and linear optics. In this setting, we find that the security only degrades by an additive constant and the protocol is able to verify positions up to 47 dB channel loss.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"streltsov-chitambar-rana-bera-winter-lewenstein-entanglementandcoherenceinquantumstatemerging-2016\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Entanglement and Coherence in Quantum State Merging.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Streltsov,  A.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Rana,  S.; Bera,  M.; Winter,  A.;  and Lewenstein,  M.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 116(24).  2016.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.116.240405\"\n     onclick=\"log_download('streltsov-chitambar-rana-bera-winter-lewenstein-entanglementandcoherenceinquantumstatemerging-2016', 'http://doi.org/10.1103/PhysRevLett.116.240405', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/streltsov-chitambar-rana-bera-winter-lewenstein-entanglementandcoherenceinquantumstatemerging-2016\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('streltsov-chitambar-rana-bera-winter-lewenstein-entanglementandcoherenceinquantumstatemerging-2016')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Entanglement and Coherence in Quantum State Merging},\n type = {article},\n year = {2016},\n volume = {116},\n id = {a8d15d70-122f-3796-9f10-5b650bc7e4b8},\n created = {2020-08-20T19:55:40.608Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.608Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2016 American Physical Society. Understanding the resource consumption in distributed scenarios is one of the main goals of quantum information theory. A prominent example for such a scenario is the task of quantum state merging, where two parties aim to merge their tripartite quantum state parts. In standard quantum state merging, entanglement is considered to be an expensive resource, while local quantum operations can be performed at no additional cost. However, recent developments show that some local operations could be more expensive than others: it is reasonable to distinguish between local incoherent operations and local operations which can create coherence. This idea leads us to the task of incoherent quantum state merging, where one of the parties has free access to local incoherent operations only. In this case the resources of the process are quantified by pairs of entanglement and coherence. Here, we develop tools for studying this process and apply them to several relevant scenarios. While quantum state merging can lead to a gain of entanglement, our results imply that no merging procedure can gain entanglement and coherence at the same time. We also provide a general lower bound on the entanglement-coherence sum and show that the bound is tight for all pure states. Our results also lead to an incoherent version of Schumacher compression: in this case the compression rate is equal to the von Neumann entropy of the diagonal elements of the corresponding quantum state.},\n bibtype = {article},\n author = {Streltsov, A. and Chitambar, E. and Rana, S. and Bera, M.N. and Winter, A. and Lewenstein, M.},\n doi = {10.1103/PhysRevLett.116.240405},\n journal = {Physical Review Letters},\n number = {24}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2016 American Physical Society. Understanding the resource consumption in distributed scenarios is one of the main goals of quantum information theory. A prominent example for such a scenario is the task of quantum state merging, where two parties aim to merge their tripartite quantum state parts. In standard quantum state merging, entanglement is considered to be an expensive resource, while local quantum operations can be performed at no additional cost. However, recent developments show that some local operations could be more expensive than others: it is reasonable to distinguish between local incoherent operations and local operations which can create coherence. This idea leads us to the task of incoherent quantum state merging, where one of the parties has free access to local incoherent operations only. In this case the resources of the process are quantified by pairs of entanglement and coherence. Here, we develop tools for studying this process and apply them to several relevant scenarios. While quantum state merging can lead to a gain of entanglement, our results imply that no merging procedure can gain entanglement and coherence at the same time. We also provide a general lower bound on the entanglement-coherence sum and show that the bound is tight for all pure states. Our results also lead to an incoherent version of Schumacher compression: in this case the compression rate is equal to the von Neumann entropy of the diagonal elements of the corresponding quantum state.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-streltsov-rana-bera-adesso-lewenstein-assisteddistillationofquantumcoherence-2016\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Assisted Distillation of Quantum Coherence.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Streltsov,  A.; Rana,  S.; Bera,  M.; Adesso,  G.;  and Lewenstein,  M.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 116(7).  2016.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.116.070402\"\n     onclick=\"log_download('chitambar-streltsov-rana-bera-adesso-lewenstein-assisteddistillationofquantumcoherence-2016', 'http://doi.org/10.1103/PhysRevLett.116.070402', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-streltsov-rana-bera-adesso-lewenstein-assisteddistillationofquantumcoherence-2016\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>2 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-streltsov-rana-bera-adesso-lewenstein-assisteddistillationofquantumcoherence-2016')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Assisted Distillation of Quantum Coherence},\n type = {article},\n year = {2016},\n volume = {116},\n id = {b5a2dda9-8007-3be0-8d57-ae0a1d4b785f},\n created = {2020-08-20T19:55:40.655Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.655Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2016 American Physical Society. We introduce and study the task of assisted coherence distillation. This task arises naturally in bipartite systems where both parties work together to generate the maximal possible coherence on one of the subsystems. Only incoherent operations are allowed on the target system, while general local quantum operations are permitted on the other; this is an operational paradigm that we call local quantum-incoherent operations and classical communication. We show that the asymptotic rate of assisted coherence distillation for pure states is equal to the coherence of assistance, an analog of the entanglement of assistance, whose properties we characterize. Our findings imply a novel interpretation of the von Neumann entropy: it quantifies the maximum amount of extra quantum coherence a system can gain when receiving assistance from a collaborative party. Our results are generalized to coherence localization in a multipartite setting and possible applications are discussed.},\n bibtype = {article},\n author = {Chitambar, E. and Streltsov, A. and Rana, S. and Bera, M.N. and Adesso, G. and Lewenstein, M.},\n doi = {10.1103/PhysRevLett.116.070402},\n journal = {Physical Review Letters},\n number = {7}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2016 American Physical Society. We introduce and study the task of assisted coherence distillation. This task arises naturally in bipartite systems where both parties work together to generate the maximal possible coherence on one of the subsystems. Only incoherent operations are allowed on the target system, while general local quantum operations are permitted on the other; this is an operational paradigm that we call local quantum-incoherent operations and classical communication. We show that the asymptotic rate of assisted coherence distillation for pure states is equal to the coherence of assistance, an analog of the entanglement of assistance, whose properties we characterize. Our findings imply a novel interpretation of the von Neumann entropy: it quantifies the maximum amount of extra quantum coherence a system can gain when receiving assistance from a collaborative party. Our results are generalized to coherence localization in a multipartite setting and possible applications are discussed.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"qi-lo-lim-siopsis-chitambar-pooser-evans-grice-freespacereconfigurablequantumkeydistributionnetwork-2016\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Free-space reconfigurable quantum key distribution network.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Qi,  B.; Lo,  H.; Lim,  C.; Siopsis,  G.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Pooser,  R.; Evans,  P.;  and Grice,  W.\n</span>\n\n  \n\n</span>\n\n  In <i>2015 IEEE International Conference on Space Optical Systems and Applications, ICSOS 2015</i>,  2016. \n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1109/ICSOS.2015.7425063\"\n     onclick=\"log_download('qi-lo-lim-siopsis-chitambar-pooser-evans-grice-freespacereconfigurablequantumkeydistributionnetwork-2016', 'http://doi.org/10.1109/ICSOS.2015.7425063', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/qi-lo-lim-siopsis-chitambar-pooser-evans-grice-freespacereconfigurablequantumkeydistributionnetwork-2016\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('qi-lo-lim-siopsis-chitambar-pooser-evans-grice-freespacereconfigurablequantumkeydistributionnetwork-2016')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@inproceedings{\n title = {Free-space reconfigurable quantum key distribution network},\n type = {inproceedings},\n year = {2016},\n id = {958d0a84-e026-34d2-8685-758e8b7313e9},\n created = {2020-08-20T19:55:40.664Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.664Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2015 IEEE. We propose a free-space reconfigurable quantum key distribution (QKD) network to secure communication among mobile users. Depends on the trustworthiness of the network relay, the users can implement either the highly secure measurement-device-independent QKD, or the highly efficient decoy state BB84 QKD. Based on the same quantum infrastructure, we also propose a loss tolerant quantum position verification scheme, which could allow the QKD users to initiate the QKD process without relying on pre-shared key.},\n bibtype = {inproceedings},\n author = {Qi, B. and Lo, H.-K. and Lim, C.C.W. and Siopsis, G. and Chitambar, E.A. and Pooser, R. and Evans, P.G. and Grice, W.},\n doi = {10.1109/ICSOS.2015.7425063},\n booktitle = {2015 IEEE International Conference on Space Optical Systems and Applications, ICSOS 2015}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2015 IEEE. We propose a free-space reconfigurable quantum key distribution (QKD) network to secure communication among mobile users. Depends on the trustworthiness of the network relay, the users can implement either the highly secure measurement-device-independent QKD, or the highly efficient decoy state BB84 QKD. Based on the same quantum infrastructure, we also propose a loss tolerant quantum position verification scheme, which could allow the QKD users to initiate the QKD process without relying on pre-shared key.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2015\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2015')\"\n      onkeypress=\"toggleGroup('group_2015')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2015</span>\n      <span class=\"bibbase_group_count\">\n        \n        (3)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"chitambar-fortescue-hsieh-distributionsattainingsecretkeyatarateoftheconditionalmutualinformation-2015\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Distributions attaining secret key at a rate of the conditional mutual information.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Fortescue,  B.;  and Hsieh,  M.\n</span>\n\n  \n\n</span>\n\n  Volume 9216  2015.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1007/978-3-662-48000-7_22\"\n     onclick=\"log_download('chitambar-fortescue-hsieh-distributionsattainingsecretkeyatarateoftheconditionalmutualinformation-2015', 'http://doi.org/10.1007/978-3-662-48000-7_22', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-fortescue-hsieh-distributionsattainingsecretkeyatarateoftheconditionalmutualinformation-2015\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-fortescue-hsieh-distributionsattainingsecretkeyatarateoftheconditionalmutualinformation-2015')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@book{\n title = {Distributions attaining secret key at a rate of the conditional mutual information},\n type = {book},\n year = {2015},\n source = {Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)},\n keywords = {Gàcs-Körner Common Information,Information-theoretic security,Public key agreement},\n volume = {9216},\n id = {3bb5d92c-fa13-3ef1-b853-8acd18d2561a},\n created = {2020-08-20T19:55:40.096Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.096Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© International Association for Cryptologic Research 2015. In this paper we consider the problem of extracting secret key from an eavesdropped source pXY Z at a rate given by the conditional mutual information. We investigate this question under three different scenarios: (i) Alice (X) and Bob (Y) are unable to communicate but share common randomness with the eavesdropper Eve (Z), (ii) Alice and Bob are allowed one-way public communication, and (iii) Alice and Bob are allowed two-way public communication. Distributions having a key rate of the conditional mutual information are precisely those in which a “helping” Eve offers Alice and Bob no greater advantage for obtaining secret key than a fully adversarial one. For each of the above scenarios, strong necessary conditions are derived on the structure of distributions attaining a secret key rate of I(X: Y |Z). In obtaining our results, we completely solve the problem of secret key distillation under scenario (i) and identify H(S|Z) to be the optimal key rate using shared randomness, where S is the Gàcs-Körner Common Information. We thus provide an operational interpretation of the conditional Gàcs- Körner Common Information. Additionally, we introduce simple example distributions in which the rate I(X: Y |Z) is achievable if and only if two-way communication is allowed.},\n bibtype = {book},\n author = {Chitambar, E. and Fortescue, B. and Hsieh, M.-H.},\n doi = {10.1007/978-3-662-48000-7_22}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © International Association for Cryptologic Research 2015. In this paper we consider the problem of extracting secret key from an eavesdropped source pXY Z at a rate given by the conditional mutual information. We investigate this question under three different scenarios: (i) Alice (X) and Bob (Y) are unable to communicate but share common randomness with the eavesdropper Eve (Z), (ii) Alice and Bob are allowed one-way public communication, and (iii) Alice and Bob are allowed two-way public communication. Distributions having a key rate of the conditional mutual information are precisely those in which a “helping” Eve offers Alice and Bob no greater advantage for obtaining secret key than a fully adversarial one. For each of the above scenarios, strong necessary conditions are derived on the structure of distributions attaining a secret key rate of I(X: Y |Z). In obtaining our results, we completely solve the problem of secret key distillation under scenario (i) and identify H(S|Z) to be the optimal key rate using shared randomness, where S is the Gàcs-Körner Common Information. We thus provide an operational interpretation of the conditional Gàcs- Körner Common Information. Additionally, we introduce simple example distributions in which the rate I(X: Y |Z) is achievable if and only if two-way communication is allowed.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-fortescue-hsieh-classicalanalogtoentanglementreversibility-2015\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Classical Analog to Entanglement Reversibility.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Fortescue,  B.;  and Hsieh,  M.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 115(9).  2015.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.115.090501\"\n     onclick=\"log_download('chitambar-fortescue-hsieh-classicalanalogtoentanglementreversibility-2015', 'http://doi.org/10.1103/PhysRevLett.115.090501', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-fortescue-hsieh-classicalanalogtoentanglementreversibility-2015\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-fortescue-hsieh-classicalanalogtoentanglementreversibility-2015')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Classical Analog to Entanglement Reversibility},\n type = {article},\n year = {2015},\n volume = {115},\n id = {3add2917-c28c-377b-9275-2a1cec39c388},\n created = {2020-08-20T19:55:40.119Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.119Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2015 American Physical Society. In this Letter we study the problem of secrecy reversibility. This asks when two honest parties can distill secret bits from some tripartite distribution pXYZ and transform secret bits back into pXYZ at equal rates using local operation and public communication. This is the classical analog to the well-studied problem of reversibly concentrating and diluting entanglement in a quantum state. We identify the structure of distributions possessing reversible secrecy when one of the honest parties holds a binary distribution, and it is possible that all reversible distributions have this form. These distributions are more general than what is obtained by simply constructing a classical analog to the family of quantum states known to have reversible entanglement. An indispensable tool used in our analysis is a conditional form of the Gács-Körner common information.},\n bibtype = {article},\n author = {Chitambar, E. and Fortescue, B. and Hsieh, M.-H.},\n doi = {10.1103/PhysRevLett.115.090501},\n journal = {Physical Review Letters},\n number = {9}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2015 American Physical Society. In this Letter we study the problem of secrecy reversibility. This asks when two honest parties can distill secret bits from some tripartite distribution pXYZ and transform secret bits back into pXYZ at equal rates using local operation and public communication. This is the classical analog to the well-studied problem of reversibly concentrating and diluting entanglement in a quantum state. We identify the structure of distributions possessing reversible secrecy when one of the honest parties holds a binary distribution, and it is possible that all reversible distributions have this form. These distributions are more general than what is obtained by simply constructing a classical analog to the family of quantum states known to have reversible entanglement. An indispensable tool used in our analysis is a conditional form of the Gács-Körner common information.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-abunada-ceballos-byrd-restrictionsoninitialsystemenvironmentcorrelationsbasedonthedynamicsofanopenquantumsystem-2015\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Restrictions on initial system-environment correlations based on the dynamics of an open quantum system.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Abu-Nada,  A.; Ceballos,  R.;  and Byrd,  M.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A - Atomic, Molecular, and Optical Physics</i>, 92(5).  2015.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.92.052110\"\n     onclick=\"log_download('chitambar-abunada-ceballos-byrd-restrictionsoninitialsystemenvironmentcorrelationsbasedonthedynamicsofanopenquantumsystem-2015', 'http://doi.org/10.1103/PhysRevA.92.052110', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-abunada-ceballos-byrd-restrictionsoninitialsystemenvironmentcorrelationsbasedonthedynamicsofanopenquantumsystem-2015\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>1 download</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-abunada-ceballos-byrd-restrictionsoninitialsystemenvironmentcorrelationsbasedonthedynamicsofanopenquantumsystem-2015')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Restrictions on initial system-environment correlations based on the dynamics of an open quantum system},\n type = {article},\n year = {2015},\n volume = {92},\n id = {b3913c87-5a45-3b64-98f2-ea310ec10e78},\n created = {2020-08-20T19:55:40.428Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.428Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2015 American Physical Society. The dynamics of an open quantum system is often modeled by introducing a bath initially in a product state with the system, letting the system and bath evolve unitarily together, and then tracing over the bath. However, often this model may not accurately reflect a particular experimental situation. Here, we provide some restrictions on one&#x27;s ability to model an open quantum system using an initial product state when some information about the system-bath interaction is known. For instance, when certain symmetries exist in the system-bath interaction, we compute limitations on how much the system&#x27;s purity can be increased if the bath is initially uncorrelated white noise. Furthermore, when the system and bath are qubits, we find that effectively only swap and product unitaries always generate system dynamics capable of being modeled using an initial product state. Finally, we show how any initial correlations between the system and environment are detectable, in principle, by observing the system transformation alone during certain joint evolutions. Our results have application in experimental quantum control and quantum computing where the system and environment are often assumed to be initially uncorrelated.},\n bibtype = {article},\n author = {Chitambar, E. and Abu-Nada, A. and Ceballos, R. and Byrd, M.},\n doi = {10.1103/PhysRevA.92.052110},\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\n number = {5}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2015 American Physical Society. The dynamics of an open quantum system is often modeled by introducing a bath initially in a product state with the system, letting the system and bath evolve unitarily together, and then tracing over the bath. However, often this model may not accurately reflect a particular experimental situation. Here, we provide some restrictions on one's ability to model an open quantum system using an initial product state when some information about the system-bath interaction is known. For instance, when certain symmetries exist in the system-bath interaction, we compute limitations on how much the system's purity can be increased if the bath is initially uncorrelated white noise. Furthermore, when the system and bath are qubits, we find that effectively only swap and product unitaries always generate system dynamics capable of being modeled using an initial product state. Finally, we show how any initial correlations between the system and environment are detectable, in principle, by observing the system transformation alone during certain joint evolutions. Our results have application in experimental quantum control and quantum computing where the system and environment are often assumed to be initially uncorrelated.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2014\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2014')\"\n      onkeypress=\"toggleGroup('group_2014')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2014</span>\n      <span class=\"bibbase_group_count\">\n        \n        (4)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"chitambar-hsieh-asymptoticstatediscriminationandastricthierarchyindistinguishabilitynorms-2014\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Asymptotic state discrimination and a strict hierarchy in distinguishability norms.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Hsieh,  M.\n</span>\n\n  \n\n</span>\n\n  <i>Journal of Mathematical Physics</i>, 55(11).  2014.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1063/1.4902027\"\n     onclick=\"log_download('chitambar-hsieh-asymptoticstatediscriminationandastricthierarchyindistinguishabilitynorms-2014', 'http://doi.org/10.1063/1.4902027', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-hsieh-asymptoticstatediscriminationandastricthierarchyindistinguishabilitynorms-2014\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>1 download</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-hsieh-asymptoticstatediscriminationandastricthierarchyindistinguishabilitynorms-2014')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Asymptotic state discrimination and a strict hierarchy in distinguishability norms},\n type = {article},\n year = {2014},\n volume = {55},\n id = {56338a86-377c-31b5-be61-0acb6f727ef9},\n created = {2020-08-20T19:55:39.872Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.872Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2014 AIP Publishing LLC. In this paper, we consider the problem of discriminating quantum states by local operations and classical communication (LOCC) when an arbitrarily small amount of error is permitted. This paradigm is known as asymptotic state discrimination, and we derive necessary conditions for when two multipartite states of any size can be discriminated perfectly by asymptotic LOCC. We use this new criterion to prove a gap in the LOCC and separable distinguishability norms. We then turn to the operational advantage of using two-way classical communication over one-way communication in LOCC processing. With a simple two-qubit product state ensemble, we demonstrate a strict majorization of the two-way LOCC norm over the one-way norm.},\n bibtype = {article},\n author = {Chitambar, E. and Hsieh, M.-H.},\n doi = {10.1063/1.4902027},\n journal = {Journal of Mathematical Physics},\n number = {11}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2014 AIP Publishing LLC. In this paper, we consider the problem of discriminating quantum states by local operations and classical communication (LOCC) when an arbitrarily small amount of error is permitted. This paradigm is known as asymptotic state discrimination, and we derive necessary conditions for when two multipartite states of any size can be discriminated perfectly by asymptotic LOCC. We use this new criterion to prove a gap in the LOCC and separable distinguishability norms. We then turn to the operational advantage of using two-way classical communication over one-way communication in LOCC processing. With a simple two-qubit product state ensemble, we demonstrate a strict majorization of the two-way LOCC norm over the one-way norm.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"maxwell-chitambar-bellinequalitieswithcommunicationassistance-2014\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Bell inequalities with communication assistance.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Maxwell,  K.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A - Atomic, Molecular, and Optical Physics</i>, 89(4).  2014.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.89.042108\"\n     onclick=\"log_download('maxwell-chitambar-bellinequalitieswithcommunicationassistance-2014', 'http://doi.org/10.1103/PhysRevA.89.042108', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/maxwell-chitambar-bellinequalitieswithcommunicationassistance-2014\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('maxwell-chitambar-bellinequalitieswithcommunicationassistance-2014')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Bell inequalities with communication assistance},\n type = {article},\n year = {2014},\n volume = {89},\n id = {35f997e0-089f-3654-af0f-7ae62492f62a},\n created = {2020-08-20T19:55:39.886Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.886Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {In this paper, we consider the possible correlations between two parties using local machines and shared randomness with an additional amount of classical communication. This is a continuation of the work initiated by Bacon and Toner [Phys. Rev. Lett. 90, 157904 (2003)PRLTAO0031-900710.1103/PhysRevLett. 90.157904] who characterized the correlation polytope for 2×2 measurement settings with binary outcomes plus one bit of communication. Here, we derive a complete set of Bell inequalities for 3×2 measurement settings and a shared bit of communication. When the communication direction is fixed, nine Bell inequalities characterize the correlation polytope, whereas when the communication direction is bidirectional, 143 inequalities describe the correlations. We then prove a tight lower bound on the amount of communication needed to simulate all no-signaling correlations for a given number of measurement settings. © 2014 American Physical Society.},\n bibtype = {article},\n author = {Maxwell, K. and Chitambar, E.},\n doi = {10.1103/PhysRevA.89.042108},\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\n number = {4}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  In this paper, we consider the possible correlations between two parties using local machines and shared randomness with an additional amount of classical communication. This is a continuation of the work initiated by Bacon and Toner [Phys. Rev. Lett. 90, 157904 (2003)PRLTAO0031-900710.1103/PhysRevLett. 90.157904] who characterized the correlation polytope for 2×2 measurement settings with binary outcomes plus one bit of communication. Here, we derive a complete set of Bell inequalities for 3×2 measurement settings and a shared bit of communication. When the communication direction is fixed, nine Bell inequalities characterize the correlation polytope, whereas when the communication direction is bidirectional, 143 inequalities describe the correlations. We then prove a tight lower bound on the amount of communication needed to simulate all no-signaling correlations for a given number of measurement settings. © 2014 American Physical Society.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-duan-hsieh-whendolocaloperationsandclassicalcommunicationsufficefortwoqubitstatediscrimination-2014\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  When do local operations and classical communication suffice for two-qubit state discrimination?.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Duan,  R.;  and Hsieh,  M.\n</span>\n\n  \n\n</span>\n\n  <i>IEEE Transactions on Information Theory</i>, 60(3).  2014.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1109/TIT.2013.2295356\"\n     onclick=\"log_download('chitambar-duan-hsieh-whendolocaloperationsandclassicalcommunicationsufficefortwoqubitstatediscrimination-2014', 'http://doi.org/10.1109/TIT.2013.2295356', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-duan-hsieh-whendolocaloperationsandclassicalcommunicationsufficefortwoqubitstatediscrimination-2014\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-duan-hsieh-whendolocaloperationsandclassicalcommunicationsufficefortwoqubitstatediscrimination-2014')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {When do local operations and classical communication suffice for two-qubit state discrimination?},\n type = {article},\n year = {2014},\n keywords = {LOCC,nonlocality without entanglement,state discrimination,trine ensembles},\n volume = {60},\n id = {211f0fec-77a0-36de-ba4b-7ad78061dabb},\n created = {2020-08-20T19:55:40.163Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.163Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {In this paper, we consider the conditions under which a given ensemble of two-qubit states can be optimally distinguished by local operations and classical communication (LOCC). We begin by completing the perfect distinguishability problem of two-qubit ensembles - both for separable operations and LOCC - by providing necessary and sufficient conditions for the perfect discrimination of one pure and one mixed state. Then, for the well-known task of minimum error discrimination, it is shown that almost all two-qubit ensembles consisting of three pure states cannot be optimally discriminated using LOCC. This is surprising considering that any two pure states can be distinguished optimally by LOCC. Special attention is given to ensembles that lack entanglement, and we prove an easy sufficient condition for when a set of three product states cannot be optimally distinguished by LOCC, thus providing new examples of the phenomenon known as non-locality without entanglement. We next consider an example of N parties who each share the same state but who are ignorant of its identity. The state is drawn from the rotationally invariant trine ensemble, and we establish a tight connection between the N-copy ensemble and Shor&#x27;s lifted single-copy ensemble. For any finite N, we prove that optimal identification of the states cannot be achieved by LOCC; however, as N → ∞, LOCC can indeed discriminate the states optimally. This is the first result of its kind. Finally, we turn to the task of unambiguous discrimination and derive new lower bounds on the LOCC inconclusive probability for symmetric states. When applied to the double trine ensemble, this leads to a rather different distinguishability character than when the minimum error probability is considered. © 1963-2012 IEEE.},\n bibtype = {article},\n author = {Chitambar, E. and Duan, R. and Hsieh, M.-H.},\n doi = {10.1109/TIT.2013.2295356},\n journal = {IEEE Transactions on Information Theory},\n number = {3}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  In this paper, we consider the conditions under which a given ensemble of two-qubit states can be optimally distinguished by local operations and classical communication (LOCC). We begin by completing the perfect distinguishability problem of two-qubit ensembles - both for separable operations and LOCC - by providing necessary and sufficient conditions for the perfect discrimination of one pure and one mixed state. Then, for the well-known task of minimum error discrimination, it is shown that almost all two-qubit ensembles consisting of three pure states cannot be optimally discriminated using LOCC. This is surprising considering that any two pure states can be distinguished optimally by LOCC. Special attention is given to ensembles that lack entanglement, and we prove an easy sufficient condition for when a set of three product states cannot be optimally distinguished by LOCC, thus providing new examples of the phenomenon known as non-locality without entanglement. We next consider an example of N parties who each share the same state but who are ignorant of its identity. The state is drawn from the rotationally invariant trine ensemble, and we establish a tight connection between the N-copy ensemble and Shor's lifted single-copy ensemble. For any finite N, we prove that optimal identification of the states cannot be achieved by LOCC; however, as N → ∞, LOCC can indeed discriminate the states optimally. This is the first result of its kind. Finally, we turn to the task of unambiguous discrimination and derive new lower bounds on the LOCC inconclusive probability for symmetric states. When applied to the double trine ensemble, this leads to a rather different distinguishability character than when the minimum error probability is considered. © 1963-2012 IEEE.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-leung-maninska-ozols-winter-everythingyoualwayswantedtoknowaboutloccbutwereafraidtoask-2014\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Everything You Always Wanted to Know About LOCC (ButWere Afraid to Ask).\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Leung,  D.; Mančinska,  L.; Ozols,  M.;  and Winter,  A.\n</span>\n\n  \n\n</span>\n\n  <i>Communications in Mathematical Physics</i>, 328(1).  2014.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1007/s00220-014-1953-9\"\n     onclick=\"log_download('chitambar-leung-maninska-ozols-winter-everythingyoualwayswantedtoknowaboutloccbutwereafraidtoask-2014', 'http://doi.org/10.1007/s00220-014-1953-9', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-leung-maninska-ozols-winter-everythingyoualwayswantedtoknowaboutloccbutwereafraidtoask-2014\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>2 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-leung-maninska-ozols-winter-everythingyoualwayswantedtoknowaboutloccbutwereafraidtoask-2014')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Everything You Always Wanted to Know About LOCC (ButWere Afraid to Ask)},\n type = {article},\n year = {2014},\n volume = {328},\n id = {893a4a8b-b751-3122-ba65-52cbe6748e39},\n created = {2020-08-20T19:55:40.559Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.559Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2014, Springer-Verlag Berlin Heidelberg. In this paper we study the subset of generalized quantum measurements on finite dimensional systems known as local operations and classical communication (LOCC). While LOCC emerges as the natural class of operations in many important quantum information tasks, its mathematical structure is complex and difficult to characterize. Here we provide a precise description of LOCC and related operational classes in terms of quantum instruments. Our formalism captures both finite round protocols as well as those that utilize an unbounded number of communication rounds.While the set of LOCC is not topologically closed, we show that finite round LOCC constitutes a compact subset of quantum operations. Additionally we show the existence of an open ball around the completely depolarizing map that consists entirely of LOCC implementable maps. Finally, we demonstrate a two-qubit map whose action can be approached arbitrarily close using LOCC, but nevertheless cannot be implemented perfectly.},\n bibtype = {article},\n author = {Chitambar, E. and Leung, D. and Mančinska, L. and Ozols, M. and Winter, A.},\n doi = {10.1007/s00220-014-1953-9},\n journal = {Communications in Mathematical Physics},\n number = {1}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  © 2014, Springer-Verlag Berlin Heidelberg. In this paper we study the subset of generalized quantum measurements on finite dimensional systems known as local operations and classical communication (LOCC). While LOCC emerges as the natural class of operations in many important quantum information tasks, its mathematical structure is complex and difficult to characterize. Here we provide a precise description of LOCC and related operational classes in terms of quantum instruments. Our formalism captures both finite round protocols as well as those that utilize an unbounded number of communication rounds.While the set of LOCC is not topologically closed, we show that finite round LOCC constitutes a compact subset of quantum operations. Additionally we show the existence of an open ball around the completely depolarizing map that consists entirely of LOCC implementable maps. Finally, we demonstrate a two-qubit map whose action can be approached arbitrarily close using LOCC, but nevertheless cannot be implemented perfectly.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2013\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2013')\"\n      onkeypress=\"toggleGroup('group_2013')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2013</span>\n      <span class=\"bibbase_group_count\">\n        \n        (1)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"chitambar-hsieh-revisitingtheoptimaldetectionofquantuminformation-2013\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Revisiting the optimal detection of quantum information.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Hsieh,  M.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A - Atomic, Molecular, and Optical Physics</i>, 88(2).  2013.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.88.020302\"\n     onclick=\"log_download('chitambar-hsieh-revisitingtheoptimaldetectionofquantuminformation-2013', 'http://doi.org/10.1103/PhysRevA.88.020302', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-hsieh-revisitingtheoptimaldetectionofquantuminformation-2013\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>1 download</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-hsieh-revisitingtheoptimaldetectionofquantuminformation-2013')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Revisiting the optimal detection of quantum information},\n type = {article},\n year = {2013},\n volume = {88},\n id = {8826f40d-6a51-3119-b381-d63ea00cab3b},\n created = {2020-08-20T19:55:39.910Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.910Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {In 1991, Peres and Wootters wrote a seminal paper on the nonlocal processing of quantum information. We return to their classic problem and solve it in various contexts. Specifically, for discriminating the &quot;double trine&quot; ensemble with minimum error, we prove that global operations are more powerful than local operations with classical communication (LOCC). Even stronger, there exists a finite gap between the optimal LOCC probability and that obtainable by separable operations (SEP). Additionally we prove that a two-way, adaptive LOCC strategy can always beat a one-way protocol. Our results demonstrate &quot;nonlocality without entanglement&quot; in two-qubit pure states. © 2013 American Physical Society.},\n bibtype = {article},\n author = {Chitambar, E. and Hsieh, M.-H.},\n doi = {10.1103/PhysRevA.88.020302},\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\n number = {2}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  In 1991, Peres and Wootters wrote a seminal paper on the nonlocal processing of quantum information. We return to their classic problem and solve it in various contexts. Specifically, for discriminating the \"double trine\" ensemble with minimum error, we prove that global operations are more powerful than local operations with classical communication (LOCC). Even stronger, there exists a finite gap between the optimal LOCC probability and that obtainable by separable operations (SEP). Additionally we prove that a two-way, adaptive LOCC strategy can always beat a one-way protocol. Our results demonstrate \"nonlocality without entanglement\" in two-qubit pure states. © 2013 American Physical Society.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2012\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2012')\"\n      onkeypress=\"toggleGroup('group_2012')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2012</span>\n      <span class=\"bibbase_group_count\">\n        \n        (3)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"chitambar-quantumcorrelationsinhighdimensionalstatesofhighsymmetry-2012\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Quantum correlations in high-dimensional states of high symmetry.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A - Atomic, Molecular, and Optical Physics</i>, 86(3).  2012.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.86.032110\"\n     onclick=\"log_download('chitambar-quantumcorrelationsinhighdimensionalstatesofhighsymmetry-2012', 'http://doi.org/10.1103/PhysRevA.86.032110', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-quantumcorrelationsinhighdimensionalstatesofhighsymmetry-2012\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-quantumcorrelationsinhighdimensionalstatesofhighsymmetry-2012')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Quantum correlations in high-dimensional states of high symmetry},\n type = {article},\n year = {2012},\n volume = {86},\n id = {baa02e1e-43b2-3dd1-a385-61bfb09db026},\n created = {2020-08-20T19:55:39.602Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.602Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {In this article, we investigate how quantum correlations behave for the so-called Werner and pseudopure families of states. The latter refers to states formed by mixing any pure state with the totally mixed state. We derive closed expressions for the quantum discord and the relative entropy of quantumness for these families of states. For Werner states, the classical correlations are seen to vanish in high dimensions while the amount of quantum correlations remains bounded. For pseudopure states, nearly the opposite effect is observed, with both the quantum and classical correlations growing without bound as the dimension increases and only as the system becomes more entangled. In light of our calculations, we discuss how Werner states could play a role as a quantum one-time pad in cryptographic tasks and, along with isotropic states, could function as a quantum memory device designed to maximize the uncertainty tradeoff between noncommuting measurements on the individual subsystems. © 2012 American Physical Society.},\n bibtype = {article},\n author = {Chitambar, E.},\n doi = {10.1103/PhysRevA.86.032110},\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\n number = {3}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  In this article, we investigate how quantum correlations behave for the so-called Werner and pseudopure families of states. The latter refers to states formed by mixing any pure state with the totally mixed state. We derive closed expressions for the quantum discord and the relative entropy of quantumness for these families of states. For Werner states, the classical correlations are seen to vanish in high dimensions while the amount of quantum correlations remains bounded. For pseudopure states, nearly the opposite effect is observed, with both the quantum and classical correlations growing without bound as the dimension increases and only as the system becomes more entangled. In light of our calculations, we discuss how Werner states could play a role as a quantum one-time pad in cryptographic tasks and, along with isotropic states, could function as a quantum memory device designed to maximize the uncertainty tradeoff between noncommuting measurements on the individual subsystems. © 2012 American Physical Society.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-cui-lo-entanglementmonotonesforwtypestates-2012\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Entanglement monotones for W-type states.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Cui,  W.;  and Lo,  H.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A - Atomic, Molecular, and Optical Physics</i>, 85(6).  2012.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.85.062316\"\n     onclick=\"log_download('chitambar-cui-lo-entanglementmonotonesforwtypestates-2012', 'http://doi.org/10.1103/PhysRevA.85.062316', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-cui-lo-entanglementmonotonesforwtypestates-2012\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-cui-lo-entanglementmonotonesforwtypestates-2012')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Entanglement monotones for W-type states},\n type = {article},\n year = {2012},\n volume = {85},\n id = {9bfe29c1-d69b-3d97-a36d-e67f749c7517},\n created = {2020-08-20T19:55:40.183Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.183Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {In this article, we extend recent results concerning random-pair Einstein-Podolsky-Rosen distillation and the operational gap between separable operations (SEPs) and local operations with classical communication (LOCC). In particular, we consider the problem of obtaining bipartite maximal entanglement from an N-qubit W-class state (i.e., that of the form √x 0|000+√x 1|100++√x n|00) when the target pairs are a priori unspecified. We show that when x 0=0, the optimal probabilities for SEPs can be computed using semidefinite programming. On the other hand, to bound the optimal probabilities achievable by LOCC, we introduce entanglement monotones defined on the N-qubit W class of states. The LOCC monotones we construct can be increased by SEPs, and in terms of transformation success probability, we are able to quantify a gap as large as 37% between the two classes. Additionally, we demonstrate transformations ρ -n→σ -n that are feasible by SEP for any n but impossible by LOCC. © 2012 American Physical Society.},\n bibtype = {article},\n author = {Chitambar, E. and Cui, W. and Lo, H.-K.},\n doi = {10.1103/PhysRevA.85.062316},\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\n number = {6}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  In this article, we extend recent results concerning random-pair Einstein-Podolsky-Rosen distillation and the operational gap between separable operations (SEPs) and local operations with classical communication (LOCC). In particular, we consider the problem of obtaining bipartite maximal entanglement from an N-qubit W-class state (i.e., that of the form √x 0|000+√x 1|100++√x n|00) when the target pairs are a priori unspecified. We show that when x 0=0, the optimal probabilities for SEPs can be computed using semidefinite programming. On the other hand, to bound the optimal probabilities achievable by LOCC, we introduce entanglement monotones defined on the N-qubit W class of states. The LOCC monotones we construct can be increased by SEPs, and in terms of transformation success probability, we are able to quantify a gap as large as 37% between the two classes. Additionally, we demonstrate transformations ρ -n→σ -n that are feasible by SEP for any n but impossible by LOCC. © 2012 American Physical Society.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-cui-lo-increasingentanglementmonotonesbyseparableoperations-2012\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Increasing entanglement monotones by separable operations.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Cui,  W.;  and Lo,  H.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 108(24).  2012.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.108.240504\"\n     onclick=\"log_download('chitambar-cui-lo-increasingentanglementmonotonesbyseparableoperations-2012', 'http://doi.org/10.1103/PhysRevLett.108.240504', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-cui-lo-increasingentanglementmonotonesbyseparableoperations-2012\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-cui-lo-increasingentanglementmonotonesbyseparableoperations-2012')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Increasing entanglement monotones by separable operations},\n type = {article},\n year = {2012},\n volume = {108},\n id = {92f45f3d-87c7-38b3-ad64-61f91d182693},\n created = {2020-08-20T19:55:40.206Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.206Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Quantum entanglement is fundamentally related to the operational setting of local quantum operations and classical communication (LOCC). A more general class of operations known as separable operations (SEP) is often employed to approximate LOCC, but the exact difference between LOCC and SEP is unknown. In this letter, we compare the two classes in performing particular tripartite to bipartite entanglement conversions and report a gap as large as 12.5% between SEP and LOCC, which is the first known appreciable gap between the classes. Our results rely on constructing a computable entanglement monotone with a clear operational meaning that, unlike all other such monotones previously studied, is not monotonic under SEP. Finally, we prove the curious fact that convergent sequences of LOCC protocols need not be LOCC feasible in the limit. © 2012 American Physical Society.},\n bibtype = {article},\n author = {Chitambar, E. and Cui, W. and Lo, H.-K.},\n doi = {10.1103/PhysRevLett.108.240504},\n journal = {Physical Review Letters},\n number = {24}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Quantum entanglement is fundamentally related to the operational setting of local quantum operations and classical communication (LOCC). A more general class of operations known as separable operations (SEP) is often employed to approximate LOCC, but the exact difference between LOCC and SEP is unknown. In this letter, we compare the two classes in performing particular tripartite to bipartite entanglement conversions and report a gap as large as 12.5% between SEP and LOCC, which is the first known appreciable gap between the classes. Our results rely on constructing a computable entanglement monotone with a clear operational meaning that, unlike all other such monotones previously studied, is not monotonic under SEP. Finally, we prove the curious fact that convergent sequences of LOCC protocols need not be LOCC feasible in the limit. © 2012 American Physical Society.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2011\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2011')\"\n      onkeypress=\"toggleGroup('group_2011')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2011</span>\n      <span class=\"bibbase_group_count\">\n        \n        (5)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"chitambar-localquantumtransformationsrequiringinfiniteroundsofclassicalcommunication-2011\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Local quantum transformations requiring infinite rounds of classical communication.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 107(19).  2011.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.107.190502\"\n     onclick=\"log_download('chitambar-localquantumtransformationsrequiringinfiniteroundsofclassicalcommunication-2011', 'http://doi.org/10.1103/PhysRevLett.107.190502', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-localquantumtransformationsrequiringinfiniteroundsofclassicalcommunication-2011\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-localquantumtransformationsrequiringinfiniteroundsofclassicalcommunication-2011')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Local quantum transformations requiring infinite rounds of classical communication},\n type = {article},\n year = {2011},\n volume = {107},\n id = {04baa759-4863-3a0b-9c40-df596776fcb3},\n created = {2020-08-20T19:55:39.642Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.642Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {In this Letter, we investigate the number of measurement and communication rounds needed to implement certain tasks by local quantum operations and classical communication (LOCC), a relatively unexplored topic. To demonstrate the possible strong dependence on the round number, we consider the problem of converting three-qubit entanglement into two-qubit form, specifically in the random distillation setting of. We find that the number of LOCC rounds needed for a transformation can depend on the amount of entanglement distilled. In fact, for a wide range of transformations, the required number of rounds is infinite (unbounded). This represents the first concrete example of a task needing an infinite number of rounds to implement. © 2011 American Physical Society.},\n bibtype = {article},\n author = {Chitambar, E.},\n doi = {10.1103/PhysRevLett.107.190502},\n journal = {Physical Review Letters},\n number = {19}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  In this Letter, we investigate the number of measurement and communication rounds needed to implement certain tasks by local quantum operations and classical communication (LOCC), a relatively unexplored topic. To demonstrate the possible strong dependence on the round number, we consider the problem of converting three-qubit entanglement into two-qubit form, specifically in the random distillation setting of. We find that the number of LOCC rounds needed for a transformation can depend on the amount of entanglement distilled. In fact, for a wide range of transformations, the required number of rounds is infinite (unbounded). This represents the first concrete example of a task needing an infinite number of rounds to implement. © 2011 American Physical Society.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"cui-chitambar-lo-randomlydistillingwclassstatesintogeneralconfigurationsoftwopartyentanglement-2011\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Randomly distilling W-class states into general configurations of two-party entanglement.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Cui,  W.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Lo,  H.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A - Atomic, Molecular, and Optical Physics</i>, 84(5).  2011.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.84.052301\"\n     onclick=\"log_download('cui-chitambar-lo-randomlydistillingwclassstatesintogeneralconfigurationsoftwopartyentanglement-2011', 'http://doi.org/10.1103/PhysRevA.84.052301', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/cui-chitambar-lo-randomlydistillingwclassstatesintogeneralconfigurationsoftwopartyentanglement-2011\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('cui-chitambar-lo-randomlydistillingwclassstatesintogeneralconfigurationsoftwopartyentanglement-2011')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Randomly distilling W-class states into general configurations of two-party entanglement},\n type = {article},\n year = {2011},\n volume = {84},\n id = {1fe832a4-4bc3-3bd3-a230-ba8150945c56},\n created = {2020-08-20T19:55:40.250Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.250Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {In this article we obtain results for the task of converting a single N-qubit W-class state (of the form √x0|00...0+√x 1|10...0++√xN|00...1) into maximum entanglement shared between two random parties. Previous studies in random distillation have not considered how the particular choice of target pairs affects the transformation, and here we develop a strategy for distilling into general configurations of target pairs. We completely solve the problem of determining the optimal distillation probability for all three-qubit configurations and most four-qubit configurations when x0=0. Our proof involves deriving new entanglement monotones defined on the set of four-qubit W-class states. As an additional application of our results, we present new upper bounds for converting a generic W-class state into the standard W state |W N=√1N(|10...0++|00...1). © 2011 American Physical Society.},\n bibtype = {article},\n author = {Cui, W. and Chitambar, E. and Lo, H.K.},\n doi = {10.1103/PhysRevA.84.052301},\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\n number = {5}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  In this article we obtain results for the task of converting a single N-qubit W-class state (of the form √x0|00...0+√x 1|10...0++√xN|00...1) into maximum entanglement shared between two random parties. Previous studies in random distillation have not considered how the particular choice of target pairs affects the transformation, and here we develop a strategy for distilling into general configurations of target pairs. We completely solve the problem of determining the optimal distillation probability for all three-qubit configurations and most four-qubit configurations when x0=0. Our proof involves deriving new entanglement monotones defined on the set of four-qubit W-class states. As an additional application of our results, we present new upper bounds for converting a generic W-class state into the standard W state |W N=√1N(|10...0++|00...1). © 2011 American Physical Society.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-miller-shi-decidingunitaryequivalencebetweenmatrixpolynomialsandsetsofbipartitequantumstates-2011\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Deciding unitary equivalence between matrix polynomials and sets of bipartite quantum states.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Miller,  C.;  and Shi,  Y.\n</span>\n\n  \n\n</span>\n\n  <i>Quantum Information and Computation</i>, 11(9-10).  2011.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-miller-shi-decidingunitaryequivalencebetweenmatrixpolynomialsandsetsofbipartitequantumstates-2011\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>1 download</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-miller-shi-decidingunitaryequivalencebetweenmatrixpolynomialsandsetsofbipartitequantumstates-2011')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n  \n  \n  \n  \n  \n  \n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Deciding unitary equivalence between matrix polynomials and sets of bipartite quantum states},\n type = {article},\n year = {2011},\n keywords = {H zbinden,Matrix polynomials,Schwartz-zippel lemma communicated by: S braunstei,Unitary transformations},\n volume = {11},\n id = {47f31127-0f1a-3734-9de4-a259ab05f43a},\n created = {2020-08-20T19:55:40.263Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.263Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {In this brief report, we consider the equivalence between two sets of m + 1 bipartite quantum states under local unitary transformations. For pure states, this problem corresponds to the matrix algebra question of whether two degree m matrix polynomials are unitarily equivalent; i.e. UAiV† = Bi for 0 &lt; i &lt; m where U and V are unitary and (Ai, Bi) are arbitrary pairs of rectangular matrices. We present a randomized polynomial-time algorithm that solves this problem with an arbitrarily high success probability and outputs transforming matrices U and V. © Rinton Press.},\n bibtype = {article},\n author = {Chitambar, E. and Miller, C.A. and Shi, Y.},\n journal = {Quantum Information and Computation},\n number = {9-10}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  In this brief report, we consider the equivalence between two sets of m + 1 bipartite quantum states under local unitary transformations. For pure states, this problem corresponds to the matrix algebra question of whether two degree m matrix polynomials are unitarily equivalent; i.e. UAiV† = Bi for 0 < i < m where U and V are unitary and (Ai, Bi) are arbitrary pairs of rectangular matrices. We present a randomized polynomial-time algorithm that solves this problem with an arbitrarily high success probability and outputs transforming matrices U and V. © Rinton Press.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"yan-gao-chitambar-twolocalobservablesaresufficienttocharacterizemaximallyentangledstatesofnqubits-2011\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Two local observables are sufficient to characterize maximally entangled states of N qubits.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Yan,  F.; Gao,  T.;  and <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A - Atomic, Molecular, and Optical Physics</i>, 83(2).  2011.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.83.022319\"\n     onclick=\"log_download('yan-gao-chitambar-twolocalobservablesaresufficienttocharacterizemaximallyentangledstatesofnqubits-2011', 'http://doi.org/10.1103/PhysRevA.83.022319', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/yan-gao-chitambar-twolocalobservablesaresufficienttocharacterizemaximallyentangledstatesofnqubits-2011\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>1 download</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('yan-gao-chitambar-twolocalobservablesaresufficienttocharacterizemaximallyentangledstatesofnqubits-2011')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Two local observables are sufficient to characterize maximally entangled states of N qubits},\n type = {article},\n year = {2011},\n volume = {83},\n id = {e68c1f66-9a74-3301-812a-ac73d93149ba},\n created = {2020-08-20T19:55:40.291Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.291Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Maximally entangled states (MES) represent a valuable resource in quantum information processing. In N-qubit systems the MES are N-GHZ states [i.e., the collection of |GHZ N =1 √2(|00...0 +|11...1 )] and its local unitary (LU) equivalences. While it is well known that such states are uniquely stabilized by N commuting observables, in this article we consider the minimum number of noncommuting observables needed to characterize an N-qubit MES as the unique common eigenstate. Here, we prove, rather surprisingly, that in this general case any N-GHZ state can be uniquely stabilized by only two observables. Thus, for the task of MES certification, only two correlated measurements are required with each party observing the spin of his or her system along one of two directions. © 2011 American Physical Society.},\n bibtype = {article},\n author = {Yan, F. and Gao, T. and Chitambar, E.},\n doi = {10.1103/PhysRevA.83.022319},\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\n number = {2}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Maximally entangled states (MES) represent a valuable resource in quantum information processing. In N-qubit systems the MES are N-GHZ states [i.e., the collection of |GHZ N =1 √2(|00...0 +|11...1 )] and its local unitary (LU) equivalences. While it is well known that such states are uniquely stabilized by N commuting observables, in this article we consider the minimum number of noncommuting observables needed to characterize an N-qubit MES as the unique common eigenstate. Here, we prove, rather surprisingly, that in this general case any N-GHZ state can be uniquely stabilized by only two observables. Thus, for the task of MES certification, only two correlated measurements are required with each party observing the spin of his or her system along one of two directions. © 2011 American Physical Society.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chen-chitambar-modi-vacanti-detectingmultipartiteclassicalstatesandtheirresemblances-2011\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Detecting multipartite classical states and their resemblances.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Chen,  L.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Modi,  K.;  and Vacanti,  G.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A - Atomic, Molecular, and Optical Physics</i>, 83(2).  2011.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.83.020101\"\n     onclick=\"log_download('chen-chitambar-modi-vacanti-detectingmultipartiteclassicalstatesandtheirresemblances-2011', 'http://doi.org/10.1103/PhysRevA.83.020101', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chen-chitambar-modi-vacanti-detectingmultipartiteclassicalstatesandtheirresemblances-2011\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>1 download</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chen-chitambar-modi-vacanti-detectingmultipartiteclassicalstatesandtheirresemblances-2011')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Detecting multipartite classical states and their resemblances},\n type = {article},\n year = {2011},\n volume = {83},\n id = {ec0c19ae-d9ee-3052-97c2-978ccabfbecf},\n created = {2020-08-20T19:55:40.466Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.466Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {We study various types of multipartite states lying near the quantum-classical boundary. The so-called classical states are precisely those in which each party can perfectly identify a locally held state without disturbing the global state, a task known as nondisruptive local state identification (NDLID). We show NDLID to be closely related local broadcasting, and we introduce a class of states called generalized classical states which allow for both NDLID and multipartite broadcasting when the most general quantum measurements are permitted. Simple analytical methods and a physical criterion are given for detecting whether a multipartite state is classical or generalized classical. For deciding the latter, a semidefinite programming algorithm is presented which may find use in other fields such as signal processing. © 2011 American Physical Society.},\n bibtype = {article},\n author = {Chen, L. and Chitambar, E. and Modi, K. and Vacanti, G.},\n doi = {10.1103/PhysRevA.83.020101},\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\n number = {2}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  We study various types of multipartite states lying near the quantum-classical boundary. The so-called classical states are precisely those in which each party can perfectly identify a locally held state without disturbing the global state, a task known as nondisruptive local state identification (NDLID). We show NDLID to be closely related local broadcasting, and we introduce a class of states called generalized classical states which allow for both NDLID and multipartite broadcasting when the most general quantum measurements are permitted. Simple analytical methods and a physical criterion are given for detecting whether a multipartite state is classical or generalized classical. For deciding the latter, a semidefinite programming algorithm is presented which may find use in other fields such as signal processing. © 2011 American Physical Society.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2010\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2010')\"\n      onkeypress=\"toggleGroup('group_2010')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2010</span>\n      <span class=\"bibbase_group_count\">\n        \n        (5)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"cui-chitambar-lo-optimalentanglementtransformationsamongnqubitwclassstates-2010\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Optimal entanglement transformations among N-qubit W-class states.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Cui,  W.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Lo,  H.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A - Atomic, Molecular, and Optical Physics</i>, 82(6).  2010.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.82.062314\"\n     onclick=\"log_download('cui-chitambar-lo-optimalentanglementtransformationsamongnqubitwclassstates-2010', 'http://doi.org/10.1103/PhysRevA.82.062314', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/cui-chitambar-lo-optimalentanglementtransformationsamongnqubitwclassstates-2010\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('cui-chitambar-lo-optimalentanglementtransformationsamongnqubitwclassstates-2010')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Optimal entanglement transformations among N-qubit W-class states},\n type = {article},\n year = {2010},\n volume = {82},\n id = {6229a88c-87ca-3b0b-b3d4-f6fa916311ca},\n created = {2020-08-20T19:55:40.303Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.303Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {We investigate the physically allowed probabilities for transforming one N-partite W-class state to another by means of local operations assisted with classical communication. Recently, S. Kintaş and S. Turgut [J. Math. Phys.JMAPAQ0022-248810.1063/1.3481573 51, 092202 (2010)] obtained an upper bound for the maximum probability of transforming two such states. Here, we provide a simple sufficient and necessary condition for when this upper bound can be satisfied and, thus, when optimality of state transformation can be achieved. Our discussion involves obtaining lower bounds for the transformation of arbitrary W-class states and showing precisely when this bound saturates the bound of Kintaş and Turgut. Finally, we consider the question of transforming symmetric W-class states and find that, in general, the optimal one-shot procedure for converting two symmetric states requires a nonsymmetric filter by all the parties. © 2010 The American Physical Society.},\n bibtype = {article},\n author = {Cui, W. and Chitambar, E. and Lo, H.-K.},\n doi = {10.1103/PhysRevA.82.062314},\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\n number = {6}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  We investigate the physically allowed probabilities for transforming one N-partite W-class state to another by means of local operations assisted with classical communication. Recently, S. Kintaş and S. Turgut [J. Math. Phys.JMAPAQ0022-248810.1063/1.3481573 51, 092202 (2010)] obtained an upper bound for the maximum probability of transforming two such states. Here, we provide a simple sufficient and necessary condition for when this upper bound can be satisfied and, thus, when optimality of state transformation can be achieved. Our discussion involves obtaining lower bounds for the transformation of arbitrary W-class states and showing precisely when this bound saturates the bound of Kintaş and Turgut. Finally, we consider the question of transforming symmetric W-class states and find that, in general, the optimal one-shot procedure for converting two symmetric states requires a nonsymmetric filter by all the parties. © 2010 The American Physical Society.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-miller-shi-matrixpencilsandentanglementclassification-2010\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Matrix pencils and entanglement classification.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Miller,  C.;  and Shi,  Y.\n</span>\n\n  \n\n</span>\n\n  <i>Journal of Mathematical Physics</i>, 51(7).  2010.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1063/1.3459069\"\n     onclick=\"log_download('chitambar-miller-shi-matrixpencilsandentanglementclassification-2010', 'http://doi.org/10.1063/1.3459069', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-miller-shi-matrixpencilsandentanglementclassification-2010\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-miller-shi-matrixpencilsandentanglementclassification-2010')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Matrix pencils and entanglement classification},\n type = {article},\n year = {2010},\n volume = {51},\n id = {83925ba3-bf80-30de-af87-c90c4eb550d6},\n created = {2020-08-20T19:55:40.333Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.333Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Quantum entanglement plays a central role in quantum information processing. A main objective of the theory is to classify different types of entanglement according to their interconvertibility through manipulations that do not require additional entanglement to perform. While bipartite entanglement is well understood in this framework, the classification of entanglements among three or more subsystems is inherently much more difficult. In this paper, we study pure state entanglement in systems of dimension 2⊗m⊗n. Two states are considered equivalent if they can be reversibly converted from one to the other with a nonzero probability using only local quantum resources and classical communication (SLOCC). We introduce a connection between entanglement manipulations in these systems and the well-studied theory of matrix pencils. All previous attempts to study general SLOCC equivalence in such systems have relied on somewhat contrived techniques which fail to reveal the elegant structure of the problem that can be seen from the matrix pencil approach. Based on this method, we report the first polynomial-time algorithm for deciding when two 2⊗m⊗n states are SLOCC equivalent. We then proceed to present a canonical form for all 2⊗m⊗n states based on the matrix pencil construction such that two states are equivalent if and only if they have the same canonical form. Besides recovering the previously known 26 distinct SLOCC equivalence classes in 2⊗3⊗n systems, we also determine the hierarchy between these classes. © 2010 American Institute of Physics.},\n bibtype = {article},\n author = {Chitambar, E. and Miller, C.A. and Shi, Y.},\n doi = {10.1063/1.3459069},\n journal = {Journal of Mathematical Physics},\n number = {7}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Quantum entanglement plays a central role in quantum information processing. A main objective of the theory is to classify different types of entanglement according to their interconvertibility through manipulations that do not require additional entanglement to perform. While bipartite entanglement is well understood in this framework, the classification of entanglements among three or more subsystems is inherently much more difficult. In this paper, we study pure state entanglement in systems of dimension 2⊗m⊗n. Two states are considered equivalent if they can be reversibly converted from one to the other with a nonzero probability using only local quantum resources and classical communication (SLOCC). We introduce a connection between entanglement manipulations in these systems and the well-studied theory of matrix pencils. All previous attempts to study general SLOCC equivalence in such systems have relied on somewhat contrived techniques which fail to reveal the elegant structure of the problem that can be seen from the matrix pencil approach. Based on this method, we report the first polynomial-time algorithm for deciding when two 2⊗m⊗n states are SLOCC equivalent. We then proceed to present a canonical form for all 2⊗m⊗n states based on the matrix pencil construction such that two states are equivalent if and only if they have the same canonical form. Besides recovering the previously known 26 distinct SLOCC equivalence classes in 2⊗3⊗n systems, we also determine the hierarchy between these classes. © 2010 American Institute of Physics.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chitambar-duan-shi-multipartitetobipartiteentanglementtransformationsandpolynomialidentitytesting-2010\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Multipartite-to-bipartite entanglement transformations and polynomial identity testing.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Duan,  R.;  and Shi,  Y.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A - Atomic, Molecular, and Optical Physics</i>, 81(5).  2010.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.81.052310\"\n     onclick=\"log_download('chitambar-duan-shi-multipartitetobipartiteentanglementtransformationsandpolynomialidentitytesting-2010', 'http://doi.org/10.1103/PhysRevA.81.052310', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-duan-shi-multipartitetobipartiteentanglementtransformationsandpolynomialidentitytesting-2010\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>2 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-duan-shi-multipartitetobipartiteentanglementtransformationsandpolynomialidentitytesting-2010')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Multipartite-to-bipartite entanglement transformations and polynomial identity testing},\n type = {article},\n year = {2010},\n volume = {81},\n id = {3e32439c-f2a5-3109-ae5b-7e9faa269ef8},\n created = {2020-08-20T19:55:40.339Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.339Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {We consider the problem of deciding if some multiparty entangled pure state can be converted, with a nonzero success probability, into a given bipartite pure state shared between two specified parties through local quantum operations and classical communication. We show that this question is equivalent to the well-known computational problem of deciding if a multivariate polynomial is identically zero. Efficient randomized algorithms developed to study the latter can thus be applied to our question. As a result, a given transformation is possible if and only if it is generically attainable by a simple randomized protocol. © 2010 The American Physical Society.},\n bibtype = {article},\n author = {Chitambar, E. and Duan, R. and Shi, Y.},\n doi = {10.1103/PhysRevA.81.052310},\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\n number = {5}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  We consider the problem of deciding if some multiparty entangled pure state can be converted, with a nonzero success probability, into a given bipartite pure state shared between two specified parties through local quantum operations and classical communication. We show that this question is equivalent to the well-known computational problem of deciding if a multivariate polynomial is identically zero. Efficient randomized algorithms developed to study the latter can thus be applied to our question. As a result, a given transformation is possible if and only if it is generically attainable by a simple randomized protocol. © 2010 The American Physical Society.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"yu-chitambar-guo-duan-tensorrankofthetripartitestatewn-2010\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Tensor rank of the tripartite state |W n.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Yu,  N.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Guo,  C.;  and Duan,  R.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review A - Atomic, Molecular, and Optical Physics</i>, 81(1).  2010.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevA.81.014301\"\n     onclick=\"log_download('yu-chitambar-guo-duan-tensorrankofthetripartitestatewn-2010', 'http://doi.org/10.1103/PhysRevA.81.014301', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/yu-chitambar-guo-duan-tensorrankofthetripartitestatewn-2010\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('yu-chitambar-guo-duan-tensorrankofthetripartitestatewn-2010')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Tensor rank of the tripartite state |W n},\n type = {article},\n year = {2010},\n volume = {81},\n id = {d58fee13-3db1-3a9e-9623-377e7b12050c},\n created = {2020-08-20T19:55:40.473Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.473Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {Tensor rank refers to the number of product states needed to express a given multipartite quantum state. Its nonadditivity as an entanglement measure has recently been observed. In this Brief Report, we estimate the tensor rank of multiple copies of the tripartite state |W=13(|100+|010+|001). Both an upper bound and a lower bound of this rank are derived. In particular, it is proven that the rank of |W 2 is 7, thus resolving a previously open problem. Some implications of this result are discussed in terms of transformation rates between |Wn and multiple copies of the state |GHZ=12(|000+|111). © 2010 The American Physical Society.},\n bibtype = {article},\n author = {Yu, N. and Chitambar, E. and Guo, C. and Duan, R.},\n doi = {10.1103/PhysRevA.81.014301},\n journal = {Physical Review A - Atomic, Molecular, and Optical Physics},\n number = {1}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  Tensor rank refers to the number of product states needed to express a given multipartite quantum state. Its nonadditivity as an entanglement measure has recently been observed. In this Brief Report, we estimate the tensor rank of multiple copies of the tripartite state |W=13(|100+|010+|001). Both an upper bound and a lower bound of this rank are derived. In particular, it is proven that the rank of |W 2 is 7, thus resolving a previously open problem. Some implications of this result are discussed in terms of transformation rates between |Wn and multiple copies of the state |GHZ=12(|000+|111). © 2010 The American Physical Society.\n</div>\n\n\n</div>\n\n\n  <div class=\"bibbase_paper\" id=\"chen-chitambar-duan-ji-winter-tensorrankandstochasticentanglementcatalysisformultipartitepurestates-2010\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Tensor rank and stochastic entanglement catalysis for multipartite pure states.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  Chen,  L.; <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Duan,  R.; Ji,  Z.;  and Winter,  A.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 105(20).  2010.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.105.200501\"\n     onclick=\"log_download('chen-chitambar-duan-ji-winter-tensorrankandstochasticentanglementcatalysisformultipartitepurestates-2010', 'http://doi.org/10.1103/PhysRevLett.105.200501', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chen-chitambar-duan-ji-winter-tensorrankandstochasticentanglementcatalysisformultipartitepurestates-2010\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chen-chitambar-duan-ji-winter-tensorrankandstochasticentanglementcatalysisformultipartitepurestates-2010')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Tensor rank and stochastic entanglement catalysis for multipartite pure states},\n type = {article},\n year = {2010},\n volume = {105},\n id = {48b80676-6ee1-3853-8a94-4018298f4624},\n created = {2020-08-20T19:55:40.562Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.562Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {The tensor rank (also known as generalized Schmidt rank) of multipartite pure states plays an important role in the study of entanglement classifications and transformations. We employ powerful tools from the theory of homogeneous polynomials to investigate the tensor rank of symmetric states such as the tripartite state |W3=1√3(|100+|010+|001) and its N-partite generalization |WN. Previous tensor rank estimates are dramatically improved and we show that (i) three copies of |W3 have a rank of either 15 or 16, (ii) two copies of |WN have a rank of 3N-2, and (iii) n copies of |WN have a rank of O(N). A remarkable consequence of these results is that certain multipartite transformations, impossible even probabilistically, can become possible when performed in multiple-copy bunches or when assisted by some catalyzing state. This effect is impossible for bipartite pure states. © 2010 The American Physical Society.},\n bibtype = {article},\n author = {Chen, L. and Chitambar, E. and Duan, R. and Ji, Z. and Winter, A.},\n doi = {10.1103/PhysRevLett.105.200501},\n journal = {Physical Review Letters},\n number = {20}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  The tensor rank (also known as generalized Schmidt rank) of multipartite pure states plays an important role in the study of entanglement classifications and transformations. We employ powerful tools from the theory of homogeneous polynomials to investigate the tensor rank of symmetric states such as the tripartite state |W3=1√3(|100+|010+|001) and its N-partite generalization |WN. Previous tensor rank estimates are dramatically improved and we show that (i) three copies of |W3 have a rank of either 15 or 16, (ii) two copies of |WN have a rank of 3N-2, and (iii) n copies of |WN have a rank of O(N). A remarkable consequence of these results is that certain multipartite transformations, impossible even probabilistically, can become possible when performed in multiple-copy bunches or when assisted by some catalyzing state. This effect is impossible for bipartite pure states. © 2010 The American Physical Society.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2009\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2009')\"\n      onkeypress=\"toggleGroup('group_2009')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2009</span>\n      <span class=\"bibbase_group_count\">\n        \n        (1)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"chitambar-duan-nonlocalentanglementtransformationsachievablebyseparableoperations-2009\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Nonlocal Entanglement Transformations Achievable by Separable Operations.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>;  and Duan,  R.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 103(11).  2009.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.103.110502\"\n     onclick=\"log_download('chitambar-duan-nonlocalentanglementtransformationsachievablebyseparableoperations-2009', 'http://doi.org/10.1103/PhysRevLett.103.110502', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-duan-nonlocalentanglementtransformationsachievablebyseparableoperations-2009\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>1 download</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-duan-nonlocalentanglementtransformationsachievablebyseparableoperations-2009')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Nonlocal Entanglement Transformations Achievable by Separable Operations},\n type = {article},\n year = {2009},\n volume = {103},\n id = {0eba58dc-d2c5-3987-8054-189e1f7c81f4},\n created = {2020-08-20T19:55:39.933Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:39.933Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {The weird phenomenon of &quot;quantum nonlocality without entanglement&quot; means that local quantum operations assisted by classical communication constitute a proper subset of the class of separable quantum operations. Despite considerable recent advances, little is known to what extent the class of separable operations differs from local quantum operations and classical communication. In this Letter we show that separable operations are generally stronger than local quantum operations and classical communication when distilling a mixed state into a pure entangled state and thus confirm the existence of entanglement monotones that can increase under separable operations. Our finding can also be interpreted as confirming the ability of separable operations to enhance the entanglement of mixed states relative to certain measures, a sensible but important fact that has never been rigorously proven before. © 2009 The American Physical Society.},\n bibtype = {article},\n author = {Chitambar, E. and Duan, R.},\n doi = {10.1103/PhysRevLett.103.110502},\n journal = {Physical Review Letters},\n number = {11}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  The weird phenomenon of \"quantum nonlocality without entanglement\" means that local quantum operations assisted by classical communication constitute a proper subset of the class of separable quantum operations. Despite considerable recent advances, little is known to what extent the class of separable operations differs from local quantum operations and classical communication. In this Letter we show that separable operations are generally stronger than local quantum operations and classical communication when distilling a mixed state into a pure entangled state and thus confirm the existence of entanglement monotones that can increase under separable operations. Our finding can also be interpreted as confirming the ability of separable operations to enhance the entanglement of mixed states relative to certain measures, a sensible but important fact that has never been rigorously proven before. © 2009 The American Physical Society.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n  <div class=\"bibbase_group_whole\" id=\"group_2008\">\n    <div class=\"bibbase_group\"\n      onclick=\"toggleGroup('group_2008')\"\n      onkeypress=\"toggleGroup('group_2008')\"\n      tabindex=\"0\">\n      <i class=\"fa fa-angle-down bibbase_group_head_icon\"></i>&nbsp;\n      <span>2008</span>\n      <span class=\"bibbase_group_count\">\n        \n        (1)\n        \n      </span>\n    </div>\n    <div class=\"bibbase_group_body\">\n      \n  \n  <div class=\"bibbase_paper\" id=\"chitambar-duan-shi-tripartiteentanglementtransformationsandtensorrank-2008\">\n  <span class=\"bibbase_paper_titleauthoryear\">\n\n  \n  <span class=\"bibbase_paper_title\">\n  \n  \n  \n  Tripartite entanglement transformations and tensor rank.\n  \n  \n  \n</span>\n\n  <span class=\"bibbase_paper_author\">\n  <a class=\"bibbase author link\" href=\"https://quantum-entangled.ece.illinois.edu/research/\">Chitambar,  E.</a>; Duan,  R.;  and Shi,  Y.\n</span>\n\n  \n\n</span>\n\n  <i>Physical Review Letters</i>, 101(14).  2008.\n  <span class=\"note\"></span>\n\n<span class=\"bibbase_note\"></span>\n\n<br class=\"bibbase_paper_content\"/>\n\n<span class=\"bibbase_paper_content dontprint\">\n\n  \n\n  \n  <a href=\"http://doi.org/10.1103/PhysRevLett.101.140502\"\n     onclick=\"log_download('chitambar-duan-shi-tripartiteentanglementtransformationsandtensorrank-2008', 'http://doi.org/10.1103/PhysRevLett.101.140502', event.ctrlKey)\"\n     class=\"bibbase doi link\">\n    <span>doi</span></a>\n  &nbsp;\n  \n\n  \n  <a href=\"//bibbase.org/network/publication/chitambar-duan-shi-tripartiteentanglementtransformationsandtensorrank-2008\"\n     class=\"bibbase bibbase_page link\">link</a>\n  &nbsp;\n  \n\n  <a href=\"#\"\n     onclick=\"showBib(event); return false;\"\n     class=\"bibbase bibtex link\">bibtex\n    <i class=\"fa fa-caret-down\"></i></a>\n\n  \n  &nbsp;\n  <a class=\"bibbase_abstract_link bibbase link\"\n     href=\"#\"\n     onclick=\"showAbstract(event); return false;\">\n    abstract <i class=\"fa fa-caret-down\"></i></a>\n  \n\n  \n  &nbsp;\n  <span class=\"bibbase_stats_paper\" style=\"color: #777;\">\n    <span>4 downloads</span>\n  </span>\n  \n\n  <!-- <a class=\"bibbase read link hidden\" -->\n  <!--    href=\"javascript:toggleRead('chitambar-duan-shi-tripartiteentanglementtransformationsandtensorrank-2008')\" -->\n  <!--    title=\"Marking this paper as read adds it to your library on BibBase.\" -->\n  <!--    > -->\n  <!--   <i class=\"fa fa-check\"></i>&nbsp; -->\n  <!--   <span>mark as read</span> -->\n  <!-- </a> -->\n\n  &nbsp;\n  \n  \n\n</span>\n\n<div class=\"well well-small bibbase\" data-type=\"bibtex\"\n     style=\"display:none\">\n  <pre style=\"white-space: pre-wrap;\">@article{\n title = {Tripartite entanglement transformations and tensor rank},\n type = {article},\n year = {2008},\n volume = {101},\n id = {ec321753-91c8-3e30-9965-f98723cabc89},\n created = {2020-08-20T19:55:40.378Z},\n file_attached = {false},\n profile_id = {889ca0d7-cd8b-3818-bafe-550deb56f3f0},\n last_modified = {2020-08-20T19:55:40.378Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {false},\n hidden = {false},\n private_publication = {false},\n abstract = {A basic question regarding quantum entangled states is whether one can be probabilistically converted to another through local operations and classical communication exclusively. While the answer for bipartite systems is known, we show that for tripartite systems, this question encodes some of the most challenging open problems in mathematics and computer science. In particular, we show that there is no easy general criterion to determine the feasibility, and in fact, the problem is NP hard. In addition, we find obtaining the most efficient algorithm for matrix multiplication to be precisely equivalent to determining the maximum rate to convert the Greenberger-Horne-Zeilinger state to a triangular distribution of three EPR states. Our results are based on connections between multipartite entanglement and tensor rank (also called Schmidt rank), a key concept in algebraic complexity theory. © 2008 The American Physical Society.},\n bibtype = {article},\n author = {Chitambar, E. and Duan, R. and Shi, Y.},\n doi = {10.1103/PhysRevLett.101.140502},\n journal = {Physical Review Letters},\n number = {14}\n}</pre>\n</div>\n\n\n<div class=\"well well-small bibbase\" data-type=\"abstract\"\n     style=\"display:none\">\n  A basic question regarding quantum entangled states is whether one can be probabilistically converted to another through local operations and classical communication exclusively. While the answer for bipartite systems is known, we show that for tripartite systems, this question encodes some of the most challenging open problems in mathematics and computer science. In particular, we show that there is no easy general criterion to determine the feasibility, and in fact, the problem is NP hard. In addition, we find obtaining the most efficient algorithm for matrix multiplication to be precisely equivalent to determining the maximum rate to convert the Greenberger-Horne-Zeilinger state to a triangular distribution of three EPR states. Our results are based on connections between multipartite entanglement and tensor rank (also called Schmidt rank), a key concept in algebraic complexity theory. © 2008 The American Physical Society.\n</div>\n\n\n</div>\n\n\n\n\n\n    </div>\n  </div>\n\n\n\n\n  </div>\n\n\n  <!-- Modal -->\n\n  <!-- <iframe id=\"bibbase_network_frame\" -->\n  <!--         src=\"//bibbase.org/network/control\" -->\n  <!--         style=\"display: none;\"> -->\n  <!-- </iframe> -->\n\n</div>\n"}; document.write(bibbase_data.data);