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A tripartite synergistic optimization strategy for zinc-iodine batteries

Weibin Yan, Ying Liu, Jiazhen Qiu, Feipeng Tan, Jiahui Liang, Xinze Cai, Chunlong Dai, Jiangqi Zhao, Zifeng Lin

2024Nature Communications116 citationsDOIOpen Access PDF

Abstract

Abstract The energy industry has taken notice of zinc-iodine (Zn-I 2 ) batteries for their high safety, low cost, and attractive energy density. However, the shuttling of I 3 − by-products at cathode electrode and dendrite issues at Zn metal anode result in short cycle lifespan. Here, a tripartite synergistic optimization strategy is proposed, involving a MXene cathode host, a n - butanol electrolyte additive, and the in-situ solid electrolyte interface (SEI) protection. The MXene possesses catalytic ability to enhance the reaction kinetics and reduce I 3 − by-products. Meanwhile, the partially dissolved n - butanol additive can work synergistically with MXene to inhibit the shuttling of I 3 − . Besides, the n - butanol and I − in the electrolyte can synergistically improve the solvation structure of Zn 2+ . Moreover, an organic-inorganic hybrid SEI is in situ generated on the surface of the Zn anode, which induces stable non-dendritic zinc deposition. As a result, the fabricated batteries exhibit a high capacity of 0.30 mAh cm −2 and a superior energy density of 0.34 mWh cm −2 at a high specific current of 5 A g −1 across 30,000 cycles, with a minimal capacity decay of 0.0004% per cycle. This work offers a promising strategy for the subsequent research to comprehensively improve battery performance.

Topics & Concepts

IodineZincComputer scienceChemistryMaterials scienceMetallurgyAdvanced battery technologies researchElectrocatalysts for Energy ConversionPerovskite Materials and Applications