锌酸盐
流动电池
电解质
法拉第效率
氧化还原
锌
无机化学
碱性电池
化学
流量(数学)
功率流
电池(电)
化学工程
材料科学
电压
电化学
功率密度
电极
锌化合物
螯合作用
电化学储能
枝晶(数学)
自行车
作者
S. M. Tan,Zhonghao Ren,Xiyu Yao,Rui Fang,Tian Xu,Guowang Diao,Yanrong Wang,Caixing Wang
摘要
ABSTRACT Conventionally, lowering the Zn plating/stripping potential relies on strongly alkaline electrolytes that convert Zn 2+ into zincate species. However, such conditions often exacerbate Zn corrosion and severe dendrite growth. Here, we introduce an iminodiacetate (IDA 2− )‐based coordination strategy that enables reversible Zn plating/stripping under mildly alkaline conditions (pH ∼12). The hexacoordinated [Zn(IDA) 2 ] 2− shifts the Zn plating/stripping potential to −1.17 V versus SHE. A demonstrated zinc‐iodine flow battery delivers a voltage of ∼1.7 V with a peak power density of 561.5 mW cm −2 and sustains cycling over 700 cycles at 100 mA cm −2 with Zn areal capacity of 90 mAh cm −2 . This strategy is further validated in a zinc‐iron redox flow battery, achieving an operating voltage of ∼1.6 V with average Coulombic efficiency of 99.3% over 750 cycles. Collectively, these results suggest that the proposed coordination chemistry offers a promising avenue toward the development of high‐voltage long‐life zinc‐based redox flow batteries.
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