硅
阳极
材料科学
二氧化硅
纳米技术
集电器
锂(药物)
应变硅
锂离子电池
化学工程
多孔硅
晶体硅
硅烷
纳米线电池
一氧化硅
光电子学
电池(电)
复合材料
电极
化学
非晶硅
电解质
量子力学
功率(物理)
物理化学
内分泌学
工程类
物理
医学
作者
Yonhua Tzeng,Raycheng Chen,Jia Lin He
出处
期刊:Nanomaterials
[MDPI AG]
日期:2020-12-09
卷期号:10 (12): 2467-2467
被引量:16
摘要
Ubiquitous mobile electronic devices and rapidly increasing electric vehicles demand a better lithium ion battery (LIB) with a more durable and higher specific charge storage capacity than traditional graphite-based ones. Silicon is among the most promising active media since it exhibits ten times of a specific capacity. However, alloying with lithium by silicon and dissociation of the silicon-lithium alloys induce high volume changes and result in pulverization. The loss of electrical contacts by silicon with the current collector of the anode causes rapid capacity decay. We report improved anode cycling performance made of silicon flakes partially encapsulated by silicon dioxide and coated with conductive nanocarbon films and CNTs. The silicon dioxide surface layer on a silicon flake improves the physical integrity for a silicon-based anode. The exposed silicon surface provides a fast transport of lithium ions and electrons. CNTs and nanocarbon films provide electrical connections between silicon flakes and the current collector. We report a novel way of manufacturing silicon flakes partially covered by silicon dioxide through breaking oxidized silicon flakes into smaller pieces. Additionally, we demonstrate an improved cycling life and capacity retention compared to pristine silicon flakes and silicon flakes fully encapsulated by silicon dioxide. Nanocarbon coatings provide conduction channels and further improve the anode performance.
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