{"_id":"v3hN88MjESyPb8T4g","bibbaseid":"ji-ma-ma-asenbauer-passerini-streb-waterdecontaminationbypolyoxometalatefunctionalized3dprintedhierarchicalporousdevices-2018","authorIDs":["a6Lb5xRyKPMGbp4nd"],"author_short":["Ji, Y.","Ma, Y.","Ma, Y.","Asenbauer, J.","Passerini, S.","Streb, C."],"bibdata":{"title":"Water decontamination by polyoxometalate-functionalized 3D-printed hierarchical porous devices","type":"article","year":"2018","identifiers":"[object Object]","pages":"3018–3021","volume":"54","id":"47805ba6-aa4d-3413-b7d6-ca12182dc772","created":"2018-04-05T07:46:29.712Z","file_attached":false,"profile_id":"f169d264-f9f7-3ec0-b4b4-5c680ddeaa4f","last_modified":"2019-07-31T16:20:52.839Z","read":false,"starred":false,"authored":"true","confirmed":"true","hidden":false,"private_publication":false,"abstract":"© 2018 The Royal Society of Chemistry. The design of organic-inorganic hybrid composites has revolutionized application-driven materials design. Here, we show how hierarchically structured, 3D-printed ABS polymers can be surface-functionalized with lacunary polyoxometalate anions ([α-PW 9 O 34 ] 9- ) featuring heavy-metal binding sites. The resulting composite is highly porous and can be used for the removal of transition-metal pollutants from water. Thus, a facile blueprint for decentralized production of water filtration devices is reported.","bibtype":"article","author":"Ji, Y. and Ma, Y. and Ma, Y. and Asenbauer, J. and Passerini, S. and Streb, C.","journal":"Chemical Communications","number":"24","bibtex":"@article{\n title = {Water decontamination by polyoxometalate-functionalized 3D-printed hierarchical porous devices},\n type = {article},\n year = {2018},\n identifiers = {[object Object]},\n pages = {3018–3021},\n volume = {54},\n id = {47805ba6-aa4d-3413-b7d6-ca12182dc772},\n created = {2018-04-05T07:46:29.712Z},\n file_attached = {false},\n profile_id = {f169d264-f9f7-3ec0-b4b4-5c680ddeaa4f},\n last_modified = {2019-07-31T16:20:52.839Z},\n read = {false},\n starred = {false},\n authored = {true},\n confirmed = {true},\n hidden = {false},\n private_publication = {false},\n abstract = {© 2018 The Royal Society of Chemistry. The design of organic-inorganic hybrid composites has revolutionized application-driven materials design. Here, we show how hierarchically structured, 3D-printed ABS polymers can be surface-functionalized with lacunary polyoxometalate anions ([α-PW 9 O 34 ] 9- ) featuring heavy-metal binding sites. The resulting composite is highly porous and can be used for the removal of transition-metal pollutants from water. Thus, a facile blueprint for decentralized production of water filtration devices is reported.},\n bibtype = {article},\n author = {Ji, Y. and Ma, Y. and Ma, Y. and Asenbauer, J. and Passerini, S. and Streb, C.},\n journal = {Chemical Communications},\n number = {24}\n}","author_short":["Ji, Y.","Ma, Y.","Ma, Y.","Asenbauer, J.","Passerini, S.","Streb, C."],"bibbaseid":"ji-ma-ma-asenbauer-passerini-streb-waterdecontaminationbypolyoxometalatefunctionalized3dprintedhierarchicalporousdevices-2018","role":"author","urls":{},"downloads":0},"bibtype":"article","creationDate":"2020-06-22T13:06:33.694Z","downloads":0,"keywords":[],"search_terms":["water","decontamination","polyoxometalate","functionalized","printed","hierarchical","porous","devices","ji","ma","ma","asenbauer","passerini","streb"],"title":"Water decontamination by polyoxometalate-functionalized 3D-printed hierarchical porous devices","year":2018}