An Endotenon Sheath-Inspired Double-Network Binder Enables Superior Cycling Performance of Silicon Electrodes

An Endotenon Sheath-Inspired Double-Network Binder Enables Superior Cycling Performance of Silicon Electrodes

Silicon (Si) has been regarded as an alternative anode material to traditional graphite owing to its higher theoretical capacity (4200 vs. 372 mAh g−1). However, Si anodes suffer from the inherent volume expansion and unstable solid electrolyte interphase, thus experiencing fast capacity decay, whic...

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Bibliographic Details
Main Authors: Chen, Z. (Author), Cui, G. (Author), Dong, T. (Author), Jiang, M. (Author), Mu, P. (Author), Qiu, H. (Author), Tang, B. (Author), Zhang, H. (Author)
Format: Article
Language:English
Published: Springer Science and Business Media B.V. 2022
Subjects:
Alternative anode materials
Anodes
Binders
Biomechanics
Capacity decay
Cycling performance
Double-network binder
Efficiency
Electrochemical electrodes
Lithium batteries
Lithium battery
Organic acids
Poly(acrylic acid)
Silicon
Silicon anode
Silicon electrode
Silicon electrodes
Solid electrolyte interphase
Solid electrolytes
Theoretical capacity
Volume expansion
Online Access:View Fulltext in Publisher
Description
Summary:Silicon (Si) has been regarded as an alternative anode material to traditional graphite owing to its higher theoretical capacity (4200 vs. 372 mAh g−1). However, Si anodes suffer from the inherent volume expansion and unstable solid electrolyte interphase, thus experiencing fast capacity decay, which hinders their commercial application. To address this, herein, an endotenon sheath-inspired water-soluble double-network binder (DNB) is presented for resolving the bottleneck of Si anodes. The as-developed binder shows excellent adhesion, high mechanical properties, and a considerable self-healing capability mainly benefited by its supramolecular hybrid network. Apart from these advantages, this binder also induces a Li3N/LiF-rich solid electrolyte interface layer, contributing to a superior cycle stability of Si electrodes. As expected, the DNB can achieve mechanically more stable Si electrodes than traditional polyacrylic acid and pectin binders. As a result, DNB delivers superior electrochemical performance of Si/Li half cells and LiNi0.8Co0.1Mn0.1O2/Si full cells, even with a high loading of Si electrode, to traditional polyacrylic acid and pectin binders. The bioinspired binder design provides a promising route to achieve long-life Si anode-assembled lithium batteries. [InlineMediaObject not available: see fulltext.] © 2022, The Author(s).
ISBN:23116706 (ISSN)
DOI:10.1007/s40820-022-00833-5

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