Emerging strategies for the improvement of modifications in aqueous rechargeable zinc–iodine batteries: Cathode, anode, separator, and electrolyte

Yuwei Zhao, Xinyu Chen, Weina Guo, Chenyang Zha
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Abstract

Aqueous rechargeable zinc–iodine batteries have gained traction as a promising solution due to their suitable theoretical energy density, cost-effectiveness, eco-friendliness, and safety features. However, challenges such as the polyiodide shuttle effect, low iodine cathode conductivity, zinc anode dendritic growth, and the requirement for efficient separators and electrolytes hinder their commercial prospects. Hence, this review highlights recent progress in refining the core optimization strategies of zinc–iodine batteries, focusing on enhancements to the cathode, anode, separator, and electrolyte. Cathode improvements involve the addition of inorganic, organic, and hybrid materials to counteract the shuttle effect and boost redox kinetics, where these functional materials also are applied in anode modifications to curb dendritic growth and enhance cycling stability. Meanwhile, cell separator design approaches that effectively block polyiodide shuttle while promoting uniform zinc deposition are also discussed, while electrolyte innovations target zinc corrosion and polyiodide dissolution. Ultimately, the review aims to map out a strategy for developing zinc–iodine batteries that are efficient, safe, and economical, aligning with the demands of contemporary energy storage.

Abstract Image

改进锌碘水性充电电池改性的新策略:阴极、阳极、隔膜和电解液
锌碘水溶液可充电电池因其合适的理论能量密度、成本效益、生态友好性和安全特性,作为一种有前途的解决方案而备受关注。然而,聚碘穿梭效应、低碘阴极电导率、锌阳极树枝状生长以及对高效分离器和电解质的要求等挑战阻碍了其商业前景。因此,本综述着重介绍了在完善锌碘电池核心优化策略方面的最新进展,重点关注阴极、阳极、隔膜和电解液的改进。阴极的改进包括添加无机、有机和混合材料,以抵消穿梭效应并提高氧化还原动力学,这些功能性材料还可用于阳极改造,以抑制树枝状生长并提高循环稳定性。同时,还讨论了在促进锌均匀沉积的同时有效阻止多碘化物穿梭的电池分离器设计方法,以及针对锌腐蚀和多碘化物溶解的电解质创新。最后,本综述旨在为开发高效、安全、经济的锌碘电池制定战略,以满足当代能源存储的需求。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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