表征(材料科学)
材料科学
微尺度化学
纳米技术
硅
阳极
纳米尺度
显微镜
工程物理
光电子学
电极
光学
化学
数学教育
数学
物理
物理化学
工程类
作者
Dahai Yang,Yun Xin Angel Ng,Kuanxin Zhang,Qiang Chang,Junhao Chen,Liang Tong,Sheng Cheng,Yi Sun,Wangqiang Shen,Edison Huixiang Ang,Hongfa Xiang,Xiaohui Song
标识
DOI:10.1021/acsami.3c00891
摘要
Si-based rechargeable lithium-ion batteries (LIBs) have generated interest as silicon has remarkably high theoretical specific capacity. It is projected that LIBs will meet the increasing need for extensive energy storage systems, electric vehicles, and portable electronics with high energy densities. However, the Si-based LIB has a substantial problem due to the volume cycle variations brought on by Si, which result in severe capacity loss. Making Si-based anodes-enabled high-performance LIBs that are easy to utilize requires an understanding of the fading mechanism. Due to its distinct advantage in morphological changes from microscale to nanoscale, even approaching atomic resolution, electron microscopy is one of the most popular methods. Based on operando electron microscopy characterization, the general comprehension of the fading mechanism and the morphology evolution of Si-based LIBs are debated in this review. The current advancements in compositional and structural interpretation for Si-based LIBs using advanced electron microscopy characterization methods are outlined. The future development trends in pertinent silicon materials characterization methods are also highlighted, along with numerous potential research avenues for Si-based LIBs design and characterization.
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