Low-current field-assisted assembly of copper nanoparticles for current collectors

Current collectors are essential features of batteries and many other electronic devices being responsible for efficient charge transport to active electrode materials. Three-dimensional (3D), high surface area current collectors considerably improve the performance of cathodes and anodes in batteri...

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Veröffentlicht in:	Faraday discussions 2015-01, Vol.181, p.383-401
Hauptverfasser:	Liu, Lehao, Choi, Bong Gill, Tung, Siu On, Hu, Tao, Liu, Yajie, Li, Tiehu, Zhao, Tingkai, Kotov, Nicholas A
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Sprache:	eng
Schlagworte:	Accumulators ANODES Assembly CATHODES Charge transport Collectors Copper Copper - chemistry copper nanoparticles current collector electro-deposition Electrochemical Techniques Electrode materials Electrodes graphite INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY lithium ion batteries MATERIALS SCIENCE Metal Nanoparticles - chemistry metallic coatings Microscopy, Electron, Scanning Microscopy, Electron, Transmission PARTICLES porous copper nanoparticle films Self assembly Three dimensional three-dimensional electrodes
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creator	Liu, Lehao Choi, Bong Gill Tung, Siu On Hu, Tao Liu, Yajie Li, Tiehu Zhao, Tingkai Kotov, Nicholas A
description	Current collectors are essential features of batteries and many other electronic devices being responsible for efficient charge transport to active electrode materials. Three-dimensional (3D), high surface area current collectors considerably improve the performance of cathodes and anodes in batteries, but their technological implementation is impeded by the complexity of their preparation, which needs to be simple, fast, and energy efficient. Here we demonstrate that field-stimulated assembly of ∼3 nm copper nanoparticles (NPs) enables the preparation of porous Cu NP films. The use of NP dispersions enables 30× reduction of the deposition current for making functional 3D coatings. In addition to high surface area, lattice-to-lattice connectivity in the self-assembly of NPs in 3D structures enables fast charge transport. The mesoscale dimensions of out-of-plane features and the spacing between them in Cu films made by field-stimulated self-assembly of NPs provides promising morphology for current collection in lithium ion batteries (LIBs). Half-cell electrochemical models based on self-assembled films show improved specific capacity, total capacity, and cycling performance compared to traditional flat and other 3D current collectors. While integration of active electrode material into the 3D topography of the current collector needs to be improved, this study indicates that self-assembled NP films represent a viable manufacturing approach for 3D electrodes.
doi_str_mv	10.1039/c4fd00263f
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subjects	Accumulators ANODES Assembly CATHODES Charge transport Collectors Copper Copper - chemistry copper nanoparticles current collector electro-deposition Electrochemical Techniques Electrode materials Electrodes graphite INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY lithium ion batteries MATERIALS SCIENCE Metal Nanoparticles - chemistry metallic coatings Microscopy, Electron, Scanning Microscopy, Electron, Transmission PARTICLES porous copper nanoparticle films Self assembly Three dimensional three-dimensional electrodes
title	Low-current field-assisted assembly of copper nanoparticles for current collectors
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