材料科学
硅
阳极
粒度
粒径
化学气相沉积
Crystal(编程语言)
粒子(生态学)
电极
扩散
锂(药物)
化学工程
一氧化硅
沉积(地质)
复合材料
纳米技术
纳米晶硅
复合数
纳米颗粒
晶体硅
电化学
粒度分布
电流密度
矿物学
锂离子电池
纳米材料
作者
Junli Li,Chaoke Bulin,Jinling Song,bangwen Zhang,Xiaolan Li
出处
期刊:Physchem
[MDPI AG]
日期:2026-01-13
卷期号:6 (1): 4-4
标识
DOI:10.3390/physchem6010004
摘要
This study aims to fabricate magnesium-doped SiOx materials through the integrated application of physical vapor deposition and chemical vapor deposition techniques, with the objective of developing high-performance anode materials for lithium-ion batteries. With the macroscopic particle size held constant, this study endeavors to explore the impact of variations in the size of microscopic silicon crystals on the properties of the material. Under the effect of magnesium doping, the influence mechanism of different microscopic grain sizes on the reaction kinetics behavior and structural stability of the material was systematically studied. Based on the research findings, a reasonable control range for the size of silicon crystals will be proposed. The research findings indicate that both relatively small and large silicon crystals are disadvantageous for cycling performance. When the silicon crystal grain size is 5.79 nm, the composite material demonstrates a relatively high overall capacity of 1442 mAh/g and excellent cycling stability. After 100 cycles, the capacity retention rate reaches 83.82%. EIS analysis reveals that larger silicon crystals exhibit a higher lithium ion diffusion coefficient. As a result, the silicon electrodes show more remarkable rate performance. Even under a high current density of 1C, the capacity of the material can still be maintained at 1044 mAh/g.
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