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Unravelling the Complex LiOH‐Based Cathode Chemistry in Lithium–Oxygen Batteries**

Xiahui Zhang, Panpan Dong, Seunghyo Noh, Xianghui Zhang, Younghwan Cha, Su Ha, Jihoon Jang, Min‐Kyu Song

2022Angewandte Chemie International Edition22 citationsDOIOpen Access PDF

Abstract

Abstract The LiOH‐based cathode chemistry has demonstrated potential for high‐energy Li−O 2 batteries. However, the understanding of such complex chemistry remains incomplete. Herein, we use the combined experimental methods with ab initio calculations to study LiOH chemistry. We provide a unified reaction mechanism for LiOH formation during discharge via net 4 e − oxygen reduction, in which Li 2 O 2 acts as intermediate in low water‐content electrolyte but LiHO 2 as intermediate in high water‐content electrolyte. Besides, LiOH decomposes via 1 e − oxidation during charge, generating surface‐reactive hydroxyl species that degrade organic electrolytes and generate protons. These protons lead to early removal of LiOH, followed by a new high‐potential charge plateau (1 e − water oxidation). At following cycles, these accumulated protons lead to a new high‐potential discharge plateau, corresponding to water formation. Our findings shed light on understanding of 4 e − cathode chemistries in metal–air batteries.

Topics & Concepts

ChemistryElectrolyteCathodeLithium (medication)OxygenReaction mechanismInorganic chemistryRedoxChemical engineeringPhysical chemistryElectrodeOrganic chemistryCatalysisEndocrinologyMedicineEngineeringAdvanced Battery Materials and TechnologiesAdvancements in Battery MaterialsAdvanced Battery Technologies Research
Unravelling the Complex LiOH‐Based Cathode Chemistry in Lithium–Oxygen Batteries** | Litcius