材料科学
电化学储能
复合数
电解质
电化学
离子电导率
硫化物
离子
聚合物
纳米技术
快离子导体
储能
化学工程
工作(物理)
电化学窗口
能量密度
电池(电)
功率密度
复合材料
电导率
超级电容器
离子键合
材料设计
基质(化学分析)
导电聚合物
嵌入
电极
作者
Yajuan Zhang,Ying Mei Yin,Peng Sun,Xi Zhang,Jinliang Li
标识
DOI:10.1002/batt.202500652
摘要
Driven by the dual demands for high energy density and intrinsic safety in next‐generation power systems, all‐solid‐state lithium‐ion batteries (ASSLIBs) using nonflammable solid‐state electrolytes have garnered significant attention. Among the candidates, sulfide‐based solid electrolytes (SSEs) are particularly promising due to their high ionic conductivity and soft mechanical properties. However, challenges such as their sensitivity to moisture and oxygen, electrochemical instability, and poor interfacial contact with electrodes hinder their practical application. To address these bottlenecks, this review highlights recent advances in material design and interfacial engineering of sulfide‐incorporated polymer matrix and summarizes how the introduction of sulfides into binders, gel polymers, and related systems improves interfacial electrochemical properties in ASSLIBs, along with the underlying mechanisms governing their electrochemical performance. In addition, we provide an in‐depth discussion of how embedding sulfide solid electrolytes into polymer matrix enables the construction of 3D ion transport networks, elucidating how interfacial energy barrier modulation and space‐charge layer formation enhance electrochemical stability and how multilayer barrier architectures contribute to improved environmental tolerance. We believe that our work will provide both theoretical insights and a technological roadmap for the development of high‐performance ASSLIBs.
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