电池(电)
重新使用
过程(计算)
锂离子电池
电化学储能
材料科学
纳米技术
工艺工程
计算机科学
电化学
电极
废物管理
工程类
超级电容器
化学
功率(物理)
物理化学
物理
操作系统
量子力学
作者
Lei Wang,Yihao Shen,Yuanlong Liu,Pan Zeng,Junxia Meng,Tiefeng Liu,Liang Zhang
标识
DOI:10.1002/smtd.202201658
摘要
Abstract Lithium‐ion batteries (LIBs) have been ubiquitous in modern society, especially in the fields of electronic devices, electric vehicles and grid storage, while raising concerns about a tremendous number of spent batteries in the next five to ten years. As environmental awareness and resource security is gaining increasingly extensive attention, how to effectively deal with spent LIBs has become a challenging issue academically and industrially. Accordingly, the development of battery recycling has surfaced as a highly researched topic in the battery community. Recently, the structural and electrochemical restoration of recycled electrode materials have been proposed as a non‐destructive method to save more energy and chemical agents compared with mature metallurgical methods. Such a refurbishment process of electrode materials is also regarded as a reverse process of their degradation in the working condition. Notably, synchrotron radiation technology, which is previously applied to diagnose battery degrade, has started to play major roles in gaining more insight into the structural restoration of electrode materials. Here, the contribution of synchrotron radiation technology to reveal the underlying degradation and regeneration mechanisms of LIBs cathodes is highlighted, providing a theoretical basis and guidance for the direct recycling and reuse of degraded cathodes.
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