纳米技术
水溶液
储能
材料科学
氧化还原
过渡金属
插层(化学)
电极
商业化
电化学储能
计算机科学
设计要素和原则
降级(电信)
可持续能源
电化学
金属有机骨架
氢气储存
材料设计
化学
机制(生物学)
电池(电)
作者
Can Li,Ziyuan Lan,Hanghang Liu,Yunxuan Jiang,Lingfeng Zhu,Xiaoning Li,Bo‐Tian Liu
标识
DOI:10.1002/advs.202524166
摘要
Aqueous ammonium-ion batteries (AAIBs) have recently emerged as promising candidates for next-generation energy storage owing to their intrinsic safety, environmental benignity, and cost efficiency. The unique tetrahedral configuration and hydrogen-bonding capability of NH4 + enable fast ion transport and dendrite-free operation, distinguishing AAIBs from traditional metal-ion systems. However, sluggish NH4 + intercalation kinetics and electrode structure degradation have limited their practical implementation. Transition metal compounds (TMCs), with flexible oxidation states, rich redox activity, and tunable electronic structures, provide a versatile platform to address these issues. This review systematically summarizes recent progress in TMCs-based electrodes for AAIBs, encompassing oxides, sulfides, carbides, nitrides, and other related compounds. We begin by distinguishing the operational principles of AAIBs in conventional "rocking-chair" and dual-ion configurations, emphasizing their distinct charge-storage pathways and associated performance limitations. Subsequently, we elucidate the fundamental mechanisms governing ammonium-ion storage and hydrogen-bonding dynamics in governing ion transport. Finally, we outline a roadmap aimed at guiding future research efforts, offering material design insights into the commercialization of next-generation safe and sustainable aqueous energy storage technologies. Unlike previous reviews that primarily focused on hydrogen bonding, organic electrodes, or safety chemistry, this review offers a material perspective that bridges inorganic redox chemistry with NH4 +-ion dynamics.
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