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dc.contributor.author Nam, Donghyeon -
dc.contributor.author Kwon, Minseong -
dc.contributor.author Ko, Yongmin -
dc.contributor.author Huh, June -
dc.contributor.author Lee, Seung Woo -
dc.contributor.author Cho, Jinhan -
dc.date.accessioned 2021-07-14T20:08:51Z -
dc.date.available 2021-07-14T20:08:51Z -
dc.date.created 2021-03-04 -
dc.date.issued 2021-03 -
dc.identifier.citation Applied Physics Reviews, v.8, no.1, pp.011405 -
dc.identifier.issn 1931-9401 -
dc.identifier.uri http://hdl.handle.net/20.500.11750/13824 -
dc.description.abstract Despite considerable interest in textile-based battery electrodes with large surface areas and mechanical flexibility, issues have restricted further advances in the energy performance of textile electrodes. These issues include the ineffective incorporation of conductive and/or active components into textile frameworks, the poor charge transfer between energy materials, and the formation of numerous unstable interfaces within textile electrodes. Herein, we introduce an aluminum textile-based lithium-ion battery cathode with remarkable areal capacity, high rate performance, and good cycling stability. Ligand exchange reaction-induced layer-by-layer (LbL) assembly of metal nanoparticles and small molecule linkers, with subsequent metal electroplating, perfectly converted polyester textiles to 3D-porous aluminum textiles that can be used as current collectors and high-energy reservoirs. The consecutive LbL assembly of high-energy LiFePO4 and conductive indium tin oxide nanoparticles onto the aluminum textiles using small organic linkers significantly increased the areal capacity and cycling stability (at least 580 cycles) of the resultant cathode, allowing facile charge transfer within the textile electrodes. Furthermore, the areal capacity of these textile electrodes increased from 1.07 to 3.28 mA h cm-2, with an increase in the folding number from 0 to 2. © 2021 Author(s). -
dc.language English -
dc.publisher American Institute of Physics Inc. -
dc.title Aluminum textile-based binder-free nanostructured battery cathodes using a layer-by-layer assembly of metal/metal oxide nanoparticles -
dc.type Article -
dc.identifier.doi 10.1063/5.0039990 -
dc.identifier.wosid 000630910200001 -
dc.identifier.scopusid 2-s2.0-85101271292 -
dc.type.local Article(Overseas) -
dc.type.rims ART -
dc.description.journalClass 1 -
dc.citation.publicationname Applied Physics Reviews -
dc.contributor.nonIdAuthor Nam, Donghyeon -
dc.contributor.nonIdAuthor Kwon, Minseong -
dc.contributor.nonIdAuthor Huh, June -
dc.contributor.nonIdAuthor Lee, Seung Woo -
dc.contributor.nonIdAuthor Cho, Jinhan -
dc.identifier.citationVolume 8 -
dc.identifier.citationNumber 1 -
dc.identifier.citationStartPage 011405 -
dc.identifier.citationTitle Applied Physics Reviews -
dc.description.isOpenAccess N -
dc.subject.keywordPlus Aluminum -
dc.subject.keywordPlus Cathodes -
dc.subject.keywordPlus Charge transfer -
dc.subject.keywordPlus Indium compounds -
dc.subject.keywordPlus Iron compounds -
dc.subject.keywordPlus Lithium compounds -
dc.subject.keywordPlus Lithium-ion batteries -
dc.subject.keywordPlus Metal nanoparticles -
dc.subject.keywordPlus Phosphorus compounds -
dc.subject.keywordPlus Tin oxides -
dc.subject.keywordPlus High-rate performance -
dc.subject.keywordPlus Indium-tin oxide nanoparticles -
dc.subject.keywordPlus Layer-by-layer assemblies -
dc.subject.keywordPlus Ligand exchange reactions -
dc.subject.keywordPlus Lithium-ion battery cathodes -
dc.subject.keywordPlus Mechanical flexibility -
dc.subject.keywordPlus Metal electroplating -
dc.subject.keywordPlus Nanostructured batteries -
dc.subject.keywordPlus Textiles -
dc.contributor.affiliatedAuthor Nam, Donghyeon -
dc.contributor.affiliatedAuthor Kwon, Minseong -
dc.contributor.affiliatedAuthor Ko, Yongmin -
dc.contributor.affiliatedAuthor Huh, June -
dc.contributor.affiliatedAuthor Lee, Seung Woo -
dc.contributor.affiliatedAuthor Cho, Jinhan -
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