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Stable Zinc Metal Battery Development: Using Fibrous Zirconia for Rapid Surface Conduction of Zinc Ions With Modified Water Solvation Structure

Jin Seong, Sanghyeon Park, Yuna Hwang, Eun Jeong Yoon, Donghee Gueon, Jong Min Yuk, Yun‐Chan Kang, Chan‐Woo Lee, Jung Hoon Yang

2024Small13 citationsDOIOpen Access PDF

Abstract

Abstract The two most critical technical issues in Zn‐based batteries, dendrite formation, and hydrogen evolution reaction, can be simultaneously addressed by introducing negatively charged fibrous ZrO 2 as a separator. Electron redistribution between ZrO 2 and Zn 2+ ions renders the ZrO 2 surface a preferred adsorption site for Zn 2+ ions, making surface conduction the primary ion‐transport mode. Surface conduction enables fibrous ZrO 2 to exhibit a 6.54 times higher single‐Zn‐ion conductivity than that of conventional glass fiber, minimizing the concentration gradient of Zn 2+ and suppressing dendrite formation. Additionally, strong Zr─O─Zn bonding stabilizes the Zn 2+ ions with fewer solvated H 2 O molecules (≈2), preventing water molecules from approaching the electrode surface, as evidenced by a 58.8% decrease in the hydrogen evolution rate. Consequently, the cycling stability of a fibrous‐ZrO 2 ‐based Zn/Zn symmetric cell (3000 h at 1 mAh cm −2 and 5 mA cm −2 ) is approximately ten times greater than that of the conventional variant. Furthermore, a fibrous‐ZrO 2 ‐based Zn–I 2 full cell exhibits a notably high energy density (271.4 Wh kg −1 ) as well as a long lifespan (≈5000 cycles) at an ultrahigh current density (4 A g −1 ).

Topics & Concepts

Materials scienceZincAdsorptionSolvationIonMoleculeChemical engineeringDendrite (mathematics)ElectrodeSeparator (oil production)Metal ions in aqueous solutionMetalInorganic chemistryChemistryPhysical chemistryMetallurgyOrganic chemistryThermodynamicsPhysicsGeometryEngineeringMathematicsAdvanced battery technologies researchAdvanced Battery Materials and TechnologiesMembrane-based Ion Separation Techniques