电解质
材料科学
相间
电化学
电池(电)
金属锂
阴极
纳米技术
锂(药物)
限制
合理设计
溶剂化
枝晶(数学)
设计要素和原则
锂离子电池
电极
快离子导体
电化学电位
化学工程
材料设计
电化学电池
锂电池
金属
作者
He Huang,Qiujiang Dong,Xingkai Wang,J J Li,Junhao Liao,Huajun Zhou,Xin Li,Xueqian Liu,Xiaopeng Han
摘要
remains hindered by the intrinsic limitations of conventional electrolyte chemistry and unfavorable interfacial dynamics. These limitations induce Li dendrite formation, cathode structural degradation, continuous electrolyte decomposition, and progressive interphase deterioration, ultimately compromising the electrochemical reversibility, stability, and safety of LMBs. In this review, we summarize the fundamental challenges limiting LMBs and delineate the essential characteristics of ideal electrolyte chemistry and interfacial stability. Building upon these foundations, recent advances in diverse electrolyte systems are systematically discussed to elucidate how rational electrolyte design dictates solvation structures and interfacial dynamics, which in turn govern ion transport, interphase stability, and the overall electrochemical and practical performance of LMBs. Furthermore, this review highlights the integration of AI-driven electrolyte discovery, in situ characterization, and further summarizes recent progress in their practical validation in high-energy pouch cells and battery devices, thereby accelerating electrolyte design and deepening mechanistic understanding. Finally, electrolyte design principles and future perspectives are outlined to promote the development of practical, safe, and high-energy batteries.
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