Abstract
Zinc-ion batteries (ZIBs) hold immense promise as next-generation energy storage solutions, however, the practical application of zinc anodes is hindered by dendrite formation and parasitic side reactions. Engineering a stable solid- eletrolyte interphase (SEI) is crucial for addressing these issues. This study proposes a novel strategy to enhance Zn anode performance by incorporating a ZnSiF(6) additive into a standard ZnSO(4) (ZSO) electrolyte. The ZnSiF(6) additive facilitates the formation of a stable, fluorine-rich SEI on the Zn anode surface. Characterization reveals a hierarchical SEI structure, primarily composed of porous alkali zinc sulfate (ZHS) with embedded ZnF(2). This unique architecture promotes rapid zinc ion desolvation and efficient transport, enhances corrosion resistance, and mitigates hydrogen evolution. Consequently, ZnSiF(6)-modified cells exhibit exceptional cycling stability, exceeding 3000 hours at 0.5 mA cm(-2) and 560 hours at 10 mA cm(-2), significantly outperforming ZSO-based cells. The modified cells also achieve high areal capacities (10 mAh cm(-2)), indicating superior zinc utilization. This work provides key insights for designing stable electrode/electrolyte interfaces, contributing to the development of high-performance aqueous ZIBs.