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Enhanced Redox Kinetics of Aqueous I <sup>−</sup> /I <sub>2</sub> /I <sup>+</sup> Conversion Chemistry in Hydrated Eutectic Electrolyte Over a Wide Temperature Range

Ling Liu, Longhai Zhang, Yangyang Liu, Shilin Zhang, Rui Wang, Fujun Li, Hongbao Li, Junnan Hao, Chaofeng Zhang, Zaiping Guo

2025Advanced Energy Materials44 citationsDOIOpen Access PDF

Abstract

Abstract Due to the continuous I − /I 2 /I + redox couples, four‐electron zinc‐iodine aqueous batteries (4eZIBs) offer a high theoretical capacity of 422 mAh g −1 . However, sluggish iodine conversion kinetics and unstable zinc plating/stripping significantly limit their widespread adoption. Here, a cost‐effective hydrated eutectic electrolyte enriched with organic cations is developed to enhance the reversibility and kinetics of Zn deposition and four‐electron iodine conversion across a wide temperature range. Specifically, the iodophilic choline cation (Ch + ), in synergy with glycerol, significantly stabilizes I + and enhances the redox kinetics of iodine species. Concurrently, the adsorption of Ch + on the anode surface promotes the uniform deposition of Zn 2+ . Furthermore, the interaction between eutectic components and water disrupts the hydrogen bond network of free water molecules, thereby enhancing the freeze resistance of the electrolyte. Consequently, the 4eZIBs with optimized hydrated eutectic electrolyte not only demonstrate remarkable cyclability with a low‐capacity decay of 0.0016% per cycle over 15 000 cycles but also exhibit excellent temperature adaptability in a wide temperature range from −25 to 40 °C. This work provides new insights into the rational design of high‐performance 4eZIBs through the organic cation chemistry and optimized electrolyte structures.

Topics & Concepts

KineticsElectrolyteAqueous solutionRedoxEutectic systemInorganic chemistryChemical kineticsMaterials sciencePhysical chemistryChemistryAnalytical Chemistry (journal)ElectrodePhysicsOrganic chemistryQuantum mechanicsComposite materialAlloyAdvanced battery technologies researchThermal Expansion and Ionic ConductivityAdvanced Battery Materials and Technologies