钒
阴极
储能
水溶液
电解质
电化学
电流密度
电流(流体)
材料科学
电极
纳米技术
功率(物理)
化学
冶金
热力学
电气工程
工程类
物理化学
物理
量子力学
作者
Xinyue Dou,Xuefang Xie,Shuquan Liang,Guozhao Fang
标识
DOI:10.1016/j.scib.2024.01.029
摘要
Vanadium-based cathodes have received widespread attention in the field of aqueous zinc-ion batteries, presenting a promising prospect for stationary energy storage applications. However, the rapid capacity decay at low current densities has hampered their development. In particular, capacity stability at low current densities is a requisite in numerous practical applications, typically encompassing peak load regulation of the electricity grid, household energy storage systems, and uninterrupted power supplies. Despite possessing notably high specific capacities, vanadium-based materials exhibit severe instability at low current densities. Moreover, the issue of stabilizing electrode reactions at these densities for vanadium-based materials has been explored insufficiently in existing research. This review aims to investigate the matter of stability in vanadium-based materials at low current densities by concentrating on the mechanisms of capacity fading and optimization strategies. It proposes a comprehensive approach that includes electrolyte optimization, electrode modulation, and electrochemical operational conditions. Finally, we presented several crucial prospects for advancing the practical development of vanadium-based aqueous zinc-ion batteries.
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