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Bidirectionally Enhanced Reaction Kinetics in Vanadium Redox Flow Battery via Regulating Mixed-Valence States in Perovskite Electrodes

Yingqiao Jiang, Ming Li, Jiaye Ye, Lei Dai, Haoran Jiang, Ling Wang, Zhangxing He

2026Nano-Micro Letters14 citationsDOIOpen Access PDF

Abstract

Abstract Various metal oxide catalysts have been utilized to enhance the electrode reaction kinetics in vanadium redox flow battery (VRFB). However, the determining factor governing their catalysis is still insufficiently understood. Herein, selectively doping of Sr and Ce at La site of LaMnO 3 perovskite (LSMO and LCMO) was used to modulate chemical environments of Mn ion activity donors, thereby boosting vanadium redox reaction processes. Sr doping increases the valence state of Mn ions, making it easier for Mn ions to take an electron from the electrode and transfer it to V 3+ ions, which lowers the reaction energy barrier of V 3+ /V 2+ redox processes. Conversely, Ce doping decreases the Mn valence and increases the oxygen vacancies, boosting the charge transfer and mass transfer of VO 2+ /VO 2 + redox processes. Theoretical calculation further demonstrates that doping Sr and Ce enhances the vanadium ion’s ability for charge transfer and adsorption. Compared with pristine VRFB, the VRFB with LSMO- and LCMO-modified anode and cathode, respectively, exhibits an excellent energy efficiency (EE) of 67% at a high current density of 300 mA cm −2 and an increased EE of 15% at 150 mA cm −2 . This study is critical for promoting fundamental understanding and offering a design strategy for achieving superior-performance metal-based electrocatalysts in VRFB.

Topics & Concepts

RedoxFlow batteryVanadiumInorganic chemistryElectron transferAnodeCatalysisValence (chemistry)ElectrodeChemistryHalf-reactionPerovskite (structure)Materials scienceOxygen evolutionLithium vanadium phosphate batteryDopingVanadium oxideElectrocatalystIonOxideChemical engineeringTransition metalOxidation stateMetalKineticsOxygenBattery (electricity)Energy storageAdvanced battery technologies researchAdvanced oxidation water treatmentMembrane-based Ion Separation Techniques