材料科学
氧化还原
阴极保护
惰性
电解质
动力学
水溶液
动能
无机化学
催化作用
离子
电子转移
电化学
工作(物理)
化学工程
Pourbaix图
化学动力学
半反应
能量转换
纳米技术
马库斯理论
电极
作者
Weijie Fan,Liping Qin,Taghreed F. Altamimi,Zeinhom M. El‐Bahy,Bingan Lu,S. M. Shaaban,Siyu Tian,Zequan Zhao,Jiang Zhou
标识
DOI:10.1002/aenm.202504251
摘要
Abstract Although aqueous electrolytic zinc‐manganese batteries (AZMBs) have attracted significant attention due to their high theoretical energy density, their practical application has been hindered by the insufficient reversibility of the cathodic Mn 2+ /MnO 2 conversion reaction. Introducing redox mediators (RMs) as electron transfer catalysts enables the conversion of electrochemically inert “dead MnO 2 ” into active Mn 2+ ions during discharging, effectively enhancing cathodic reversibility. However, the practical application of RM‐assisted AZMB systems is severely hindered by a limited understanding of the relationship between the fundamental properties of RMs and their reaction kinetics with MnO 2 . By applying classical Marcus theory, the correlation between the fundamental structures of RMs and their reaction kinetics is elucidated, offering a coherent explanation for the conflict between the thermodynamic and kinetic behaviors of the RM‐assisted MnO 2 electroreduction process. Emphases are placed on establishing a theoretical foundation and design paradigms, including the design of organic RM molecules, construction of efficient RM‐based reaction systems, and formulation of shuttle‐free approaches, thereby designing and advancing high‐performance RM‐assisted AZMBs.
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