Nanocomposite design for solid-state lithium metal batteries: Progress, challenge, and prospects

Yong Chen , Lv Xu , Xu Yang , Qiongguang Li , Meng Yao , Guoxiu Wang
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Abstract

Lithium metal batteries have gained significant attention due to their high energy density, making them a promising candidate for various applications, including electric vehicles and grid-scale energy storage. Nevertheless, the practical development of lithium metal batteries faces challenges related to dendrite formation, low cycling efficiency, and poor safety due to the use of liquid electrolytes. Solid-state electrolytes (SSEs) are the most attractive alternatives for next-generation safe and high-energy density energy storage systems. However, conventional SSEs fail to meet the simultaneous demands of high ionic conductivity and mechanical properties, due to their intrinsic solid-state chemical properties. Among numerous modifying strategies for SSE chemistry, composite polymer electrolytes (CPEs) with advanced nanocomposite design display suitable processability, wettability, high flexibility, low density, and low cost of production. This review comprehensively outlines the merits and functions of advanced nanocomposite designs in CPEs. This review provides valuable insights into the recent progress in nanocomposite designs of solid-state electrolytes, offering guidance for future research and development efforts in this field.

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固态锂金属电池的纳米复合材料设计:进展、挑战和前景
锂金属电池因其高能量密度而备受关注,成为电动汽车和电网储能等各种应用的理想选择。然而,锂金属电池的实际开发面临着枝晶形成、循环效率低以及使用液态电解质安全性差等挑战。固态电解质(SSE)是下一代安全、高能量密度储能系统最具吸引力的替代品。然而,传统的固态电解质由于其固有的固态化学特性,无法同时满足高离子电导率和机械性能的要求。在众多固态电解质化学改性策略中,采用先进纳米复合材料设计的复合聚合物电解质(CPE)具有合适的加工性、润湿性、高灵活性、低密度和低生产成本。本综述全面概述了先进纳米复合材料设计在 CPE 中的优点和功能。本综述为固态电解质纳米复合材料设计的最新进展提供了宝贵的见解,为该领域未来的研发工作提供了指导。
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