电解质
氧化还原
电化学
电池(电)
材料科学
溶解
水溶液
合理设计
有机自由基电池
纳米技术
储能
化学工程
无机化学
过渡金属
电化学储能
碘
电子转移
电极
作者
Qianqin Zhou,Fan Zhang,Ting Liao,Ziqi Sun
标识
DOI:10.1002/adfm.202532035
摘要
ABSTRACT Aqueous zinc‐iodine (Zn‐I 2 ) batteries have gained considerable attention as safe, low‐cost energy‐storage systems, yet several intrinsic limitations continue to impede their widespread application. Major challenges associated with electrolytes, such as restricted energy density, sluggish iodine redox kinetics, dissolution of iodine species, and polyiodide shuttling, however, are considered as central bottlenecks. This review provides an integrated summary of recent developments in Zn‐I 2 battery chemistry and summarizes the electrolyte engineering strategies on accounting to different electrons transfer mechanisms in Zn‐I 2 redox chemistry. In this section, special focuses are paid on the rational design of aqueous electrolytes in balancing the iodine solubility, the polyiodide complexation, the electrolyte acidity/alkalinity, and the Zn 2+ coordination chemistry. Finally, a research outlook and a few design principles in suppressing uncontrolled shuttle and redox instability of polyiodide species while simultaneously maintaining high Zn reversibility are proposed for achieving high‐performance and durable Zn‐I 2 systems. This review aims to provide a feasible framework for advancing Zn‐I 2 battery electrochemistry and accelerating their transition toward practical, large‐scale energy‐storage applications.
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