Kinked silicon nanowires-enabled interweaving electrode configuration for lithium-ion batteries

Kinked silicon nanowires-enabled interweaving electrode configuration for lithium-ion batteries

Abstract A tri-dimensional interweaving kinked silicon nanowires (k-SiNWs) assembly, with a Ni current collector co-integrated, is evaluated as electrode configuration for lithium ion batteries. The large-scale fabrication of k-SiNWs is based on a procedure for continuous metal assisted chemical etc...

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Detalles Bibliográficos
Autores principales: Georgiana Sandu, Michael Coulombier, Vishank Kumar, Hailu G. Kassa, Ionel Avram, Ran Ye, Antoine Stopin, Davide Bonifazi, Jean-François Gohy, Philippe Leclère, Xavier Gonze, Thomas Pardoen, Alexandru Vlad, Sorin Melinte
Formato: article
Lenguaje:EN
Publicado: Nature Portfolio 2018
Materias:
Medicine
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Science
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Acceso en línea:https://doaj.org/article/4d3d61cc5f5249b79f91790f2769a7d4
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Sumario:Abstract A tri-dimensional interweaving kinked silicon nanowires (k-SiNWs) assembly, with a Ni current collector co-integrated, is evaluated as electrode configuration for lithium ion batteries. The large-scale fabrication of k-SiNWs is based on a procedure for continuous metal assisted chemical etching of Si, supported by a chemical peeling step that enables the reuse of the Si substrate. The kinks are triggered by a simple, repetitive etch-quench sequence in a HF and H2O2-based etchant. We find that the inter-locking frameworks of k-SiNWs and multi-walled carbon nanotubes exhibit beneficial mechanical properties with a foam-like behavior amplified by the kinks and a suitable porosity for a minimal electrode deformation upon Li insertion. In addition, ionic liquid electrolyte systems associated with the integrated Ni current collector repress the detrimental effects related to the Si-Li alloying reaction, enabling high cycling stability with 80% capacity retention (1695 mAh/gSi) after 100 cycles. Areal capacities of 2.42 mAh/cm2 (1276 mAh/gelectrode) can be achieved at the maximum evaluated thickness (corresponding to 1.3 mgSi/cm2). This work emphasizes the versatility of the metal assisted chemical etching for the synthesis of advanced Si nanostructures for high performance lithium ion battery electrodes.

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