离子液体
水溶液
水解
化学工程
材料科学
储能
沉积(地质)
相(物质)
氧化还原
锌
电极
离子键合
纳米技术
双水相体系
无机化学
电池(电)
化学稳定性
电化学
离子强度
腐蚀
离子
容量损失
作者
Z Xu,Yì Wáng,Peng Sun,J Li,J Li,Yaoyu Chen,Wenjie Mai,Xu M,J Li,J Li,Likun Pan
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-05-27
标识
DOI:10.1021/acsnano.6c02699
摘要
Aqueous zinc–iodine batteries are promising for grid-scale energy storage but suffer from irreversible capacity loss when pursuing the high-energy four-electron redox chemistry, primarily due to the hydrolysis of high-valent iodine species (I+) and severe corrosion of the zinc anode. Herein, we propose a polyhalide ionic-liquid phase-separation strategy enabled by the dual-functional additive 1-ethyl-3-methylimidazolium ([EMIm]+). We find that [EMIm]+ preferentially coordinates with the electrogenerated polyhalide [IBr2]− to form a hydrophobic ionic liquid (EMImIBr2), which spontaneously separates from the aqueous electrolyte. This phase separation physically isolates I+ from water, effectively suppressing hydrolysis and enabling highly reversible I0/I+ conversion. Meanwhile, [EMIm]+ mitigates Br–-induced corrosion, guides Zn deposition along the dendrite-suppressing (002) plane, and improves plating/stripping reversibility. As a result, Zn||I2 cells achieve a high specific capacity of 391.0 mAh g–1 at 0.1 A g–1 (approaching the theoretical limit of 422 mAh g–1), with an excellent rate performance (302.4 mAh g–1 at 3 A g–1), and long-term cycling stability (70% capacity retention over 2000 cycles). Practical viability is demonstrated by high-loading pouch cells delivering 190 mAh and powering electronic devices.
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