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Modulating the Spin State to Stabilize the Surface and Bulk Structure for Durable 4.6 V LiCoO<sub>2</sub> Cathodes

Ziqing Yao, Tianji Fu, Tao Pan, Zhongwei Jiang, Fan Xu, Shuangke Liu, Qingpeng Guo, Yujie Li, Chunman Zheng, Weiwei Sun

2024Advanced Functional Materials50 citationsDOI

Abstract

Abstract High‐voltage LiCoO 2 (LCO) attracts great interest due to its high theoretical capacity, however, the aggravated oxygen redox, Co dissolution, and lattice degradation at high voltage potentially induce the instability of crystal structural and cathode–electrolyte interphase, and can ultimately lead to severe capacity fading. Herein, a design strategy of spin modulation is presented to stabilize the surface and bulk structure of the commercial LiCoO 2 (C‐LCO). The prepared high‐spin state LiCoO 2 via crystal field modulation elevates the Co─O band gap, suppresses the electronic compensation of oxygen at high voltage, and reduces the side reactions of reactive oxygen and dissolved Co ions with the electrolyte, which greatly restrains the irreversible phase transition from O3 to H1‐3 and the degeneration of cathode–electrolyte interphase. As a result, the spin‐modulated LiCoO 2 shows significantly improved electrochemical performances including high discharge capacity, stable cycling behavior, and enhanced rate capability. This work based on spin modification by crystal field modulation can apply to other layered transition metal oxide cathodes, providing a new avenue for developing high‐energy–density cathodes.

Topics & Concepts

Materials scienceCathodeElectrolyteDissolutionElectrochemistryInterphaseOxideChemical engineeringNanotechnologyElectrodePhysical chemistryMetallurgyChemistryBiologyEngineeringGeneticsAdvancements in Battery MaterialsSupercapacitor Materials and FabricationAdvanced Battery Materials and Technologies
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