Environmental Control of the Topological Transition in Metal/Photoemissive-Blend Metamaterials. Caligiuri, V., Lento, R., Ricciardi, L., Termine, R., La Deda, M., Siprova, S., Golemme, A., & De Luca, A. Advanced Optical Materials, Wiley-VCH Verlag, 2018. cited By 5
Environmental Control of the Topological Transition in Metal/Photoemissive-Blend Metamaterials [link]Paper  doi  abstract   bibtex   
The quest for unconventional optical materials finds natural answers in the field of plasmonics. Here, special composites can manifest singularities in their dielectric permittivity. The so-called epsilon-near-zero (εNZ) condition is typically encountered in artificial materials called hyperbolic metamaterials (HMMs). Unfortunately, tuning the HMMs εNZ is still challenging. Here it is demonstrated how the εNZ frequency of an HMM can be reversibly tuned via thermally induced water absorption/desorption. The key element is a dielectric hygroscopic material, consisting of a blend of a polymer, a sol–gel unsintered TiO2, and an organic dye. Due to the hygroscopic nature of unsintered TiO2, an increase of temperature induces a reversible physical contraction of the thickness of the dielectric blend, as well as an increase of refractive index. This causes a remarkable 45 nm shift of the absorption peak of the embedded dye, acting as a chromatic label. When such a blend is embedded in an HMM, a reversible thermal tuning of the overall optical response, as well as an epsilon-near-zero wavelength shift by about 25 nm, is induced. The remarkable tuning range shown here, besides obvious HMM-based temperature sensing applications, paves the way toward a plethora of new functions in which tunable εNZ materials are needed. © 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
@ARTICLE{Caligiuri2018,
author={Caligiuri, V. and Lento, R. and Ricciardi, L. and Termine, R. and La Deda, M. and Siprova, S. and Golemme, A. and De Luca, A.},
title={Environmental Control of the Topological Transition in Metal/Photoemissive-Blend Metamaterials},
journal={Advanced Optical Materials},
year={2018},
volume={6},
number={9},
doi={10.1002/adom.201701380},
art_number={1701380},
note={cited By 5},
url={https://www.scopus.com/inward/record.uri?eid=2-s2.0-85042550417&doi=10.1002%2fadom.201701380&partnerID=40&md5=0079d112d0d3ef71e67779194afd973e},
abstract={The quest for unconventional optical materials finds natural answers in the field of plasmonics. Here, special composites can manifest singularities in their dielectric permittivity. The so-called epsilon-near-zero (εNZ) condition is typically encountered in artificial materials called hyperbolic metamaterials (HMMs). Unfortunately, tuning the HMMs εNZ is still challenging. Here it is demonstrated how the εNZ frequency of an HMM can be reversibly tuned via thermally induced water absorption/desorption. The key element is a dielectric hygroscopic material, consisting of a blend of a polymer, a sol–gel unsintered TiO2, and an organic dye. Due to the hygroscopic nature of unsintered TiO2, an increase of temperature induces a reversible physical contraction of the thickness of the dielectric blend, as well as an increase of refractive index. This causes a remarkable 45 nm shift of the absorption peak of the embedded dye, acting as a chromatic label. When such a blend is embedded in an HMM, a reversible thermal tuning of the overall optical response, as well as an epsilon-near-zero wavelength shift by about 25 nm, is induced. The remarkable tuning range shown here, besides obvious HMM-based temperature sensing applications, paves the way toward a plethora of new functions in which tunable εNZ materials are needed. © 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim},
publisher={Wiley-VCH Verlag},
issn={21951071},
document_type={Article},
source={Scopus},
}
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