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用于高容量锂离子电池的无粘结剂Sn-Si异质结构薄膜

Binder-free Sn-Si heterostructure films for high capacity Li-ion batteries.

作者信息

Loveridge M J, Malik R, Paul S, Manjunatha K N, Gallanti S, Tan C, Lain M, Roberts A J, Bhagat R

机构信息

WMG, Warwick University Coventry CV4 7AL UK

EMTERC, De Montfort University Leicester LE19BH UK.

出版信息

RSC Adv. 2018 May 8;8(30):16726-16737. doi: 10.1039/c7ra13489d. eCollection 2018 May 3.

DOI:10.1039/c7ra13489d
PMID:35540555
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9080329/
Abstract

This study fabricated and demonstrated a functional, stable electrode structure for a high capacity Li-ion battery (LIB) anode. Effective performance is assessed in terms of reversible lithiation for a significant number of charge-discharge cycles to 80% of initial capacity. The materials selected for this study are silicon and tin and are co-deposited using an advanced manufacturing technique (plasma-enhanced chemical vapour deposition), shown to be a scalable process that can facilitate film growth on 3D substrates. Uniform and hybrid crystalline-amorphous Si nanowire (SiNW) growth is achieved a vapour-liquid-solid mechanism using a Sn metal catalyst. SiNWs of less than 300 nm diameter are known to be less susceptible to fracture and when grown this way have direct electrical conductivity to the current collector, with sufficient room for expansion. Electrochemical characterisation shows stable cycling at capacities of 1400 mA h g (>4 × the capacity limit of graphite). This hybrid system demonstrates promising electrochemical performance, can be grown at large scale and has also been successfully grown on flexible carbon paper current collectors. These findings will have impact on the development of flexible batteries and wearable energy storage.

摘要

本研究制造并展示了一种用于高容量锂离子电池(LIB)阳极的功能性、稳定电极结构。通过大量充放电循环至初始容量的80%时的可逆锂化来评估有效性能。本研究选择的材料是硅和锡,并使用先进制造技术(等离子体增强化学气相沉积)进行共沉积,该技术显示为一种可扩展的工艺,能够促进在3D基板上的薄膜生长。利用Sn金属催化剂通过气-液-固机制实现了均匀且混合的晶体-非晶硅纳米线(SiNW)生长。已知直径小于300 nm的SiNW不易断裂,并且以这种方式生长时与集流体具有直接的导电性,具有足够的膨胀空间。电化学表征显示在1400 mA h g的容量下具有稳定的循环(>石墨容量极限的4倍)。这种混合系统展示出了有前景的电化学性能,可以大规模生长,并且也已成功生长在柔性碳纸集流体上。这些发现将对柔性电池和可穿戴储能的发展产生影响。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/27a6/9080329/228c097292a0/c7ra13489d-f12.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/27a6/9080329/c0dc2d0df487/c7ra13489d-f9.jpg
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