表面工程
材料科学
涂层
纳米技术
阴极
储能
空位缺陷
降级(电信)
失效机理
工作(物理)
可持续能源
过渡金属
机制(生物学)
清洁能源
作者
Shanzhi Dong,Haotian Yao,Ziwei Qin,Wenxian Li,Yang Liu,Yufeng Zhao
标识
DOI:10.1002/chem.202502108
摘要
Abstract Nickel‐rich layered LiNi x Co y Mn z O 2 (NCM, x 0.6) cathodes have been widely used for high‐energy‐density lithium‐ion batteries (LIBs), delivering exceptional capacity 200 mAh g −1 ) and remarkable cost‐efficiency. Nevertheless, structural degradation (e.g., oxygen vacancy formation, transition metal dissolution) and interfacial instability (side reactions) under high‐voltage operation (4.3 V) severely limit their cycle life. Recent advances demonstrate that precisely engineered surface coatings can synergistically address these limitations through suppressing parasitic reactions, stabilizing lattice frameworks, and enhancing Li + transport kinetics. This review provides a multidimensional analysis of coating engineering for NCM cathodes, focusing on the mechanism insights, innovative designs, and synthesis route. Notably, this work emphasizes emerging opportunities within underexplored research areas, specifically artificial intelligence‐enabled coating architectures and sustainable large‐scale synthesis methodologies. By systematically integrating fundamental mechanistic insights with practical engineering perspectives, a robust framework to accelerate the utilization of NCM cathodes as ultra‐stable and safe energy storage systems is established in this review.
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