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Towards Highly Stable Sn<sup>2+</sup> Electrolyte for Aqueous Tin Batteries Using Hydroquinone Antioxidant

Qiong Wang, Fengyi Zhang, Yu Shu, Hongjie Xiao, Xi Zhang, Xiaohui Ma, Jinlong Liu, Yonggang Wang, Jianhang Huang, Yongyao Xia

2024Angewandte Chemie International Edition11 citationsDOIOpen Access PDF

Abstract

Abstract Sn redox chemistry in aqueous acidic electrolyte was characterized with high reversibility and kinetics, which is considered as competitive anode material for aqueous batteries. Unfortunately, divalent Sn 2+ is unstable in aqueous electrolyte. It was revealed that Sn 2+ is easy to be oxidized to tetravalent Sn 4+ by dissolved oxygen and then forms precipitate through hydrolysis process, leading to serious performance decay. Here, hydroquinone (HQ) was employed as antioxidant to prevent Sn 2+ oxidation. With addition of HQ, Sn 2+ electrolyte can maintain transparent and colorless after long‐time exposure under air atmosphere, while large amounts of sediment were observed in the electrolyte without HQ. Moreover, HQ can adsorb on electrode surface to regulate Sn deposition and suppress Sn dendrite formation. With the difunctional HQ additive, Sn anode shows a stable cycling performance more than 1500 cycles with a high average coulombic efficiency (CE) of 99.9 %. And the organic||Sn cell shows high cycling stability for 10,000 cycles with 71 % capacity retention. The hydroquinone antioxidant strategy provides a facile and cost‐effective way to develop highly stable Sn 2+ ‐based electrolyte.

Topics & Concepts

HydroquinoneElectrolyteAqueous solutionChemistryFaraday efficiencyTinInorganic chemistryAnodeSN2 reactionRedoxHydrolysisChemical engineeringElectrodeOrganic chemistryPhysical chemistryEngineeringAdvanced battery technologies researchAdvanced Battery Materials and TechnologiesAdvancements in Battery Materials