Sulfur-based aqueous batteries (SABs) are regarded as promising candidates for safe, low-cost, and high-energy storage. However, the sluggish redox kinetics of polysulfides pose a significant challenge to the practical performance of SABs. Herein, we report a unique redox regulation strategy that leverages thiosulfate-mediated ligand-chain interaction to accelerate the polysulfide redox process (S0/S2-). The S2O3 2- species in the electrolyte can induce the rapid reduction of polysulfide through a spontaneous chemical reaction with sulfur species, while facilitating the reversible oxidation of short-chain sulfides. Moreover, the thiosulfate redox pair (S2O3 2-/S4O6 2-) within the K2S2O3 electrolyte contributes additional capacity at higher potential (E0 >0 V vs SHE). Consequently, the elaborate SAB delivers an unprecedented K+ storage capacity of 2470 mAh gs -1, coupled with a long cycling life exceeding 1000 cycles. Remarkably, thiosulfate-mediated SAB achieves an energy density of 616 Wh kgS+Zn -1, surpassing both organic K-S batteries and conventional aqueous battery systems. This work elucidates the mechanism underlying the thiosulfate-mediated polysulfide redox process, thereby opening a pathway for the development of high-energy aqueous batteries.
Keywords: K2S2O3 electrolyte; Thiosulfate-mediated polysulfide redox; aqueous battery; high-energy density; reaction kinetics.
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