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Fluorine Mediates the Deprotonation Pathway over Ruthenium Oxide for Stable Water Electrolysis

Jie Ma, Shuai-Qi Gong, Ming-Rong Qu, Xiao-Long Zhang, Long-Xing Lin, Wen-Jie Fang, He-Xing Li, Sheng Zhu, Yu-Lin Min, Min-Rui Gao

2026Journal of the American Chemical Society7 citationsDOI

Abstract

Ruthenium oxide (RuO 2 ) is a promising alternative anode catalyst to iridium oxide in proton exchange membrane water electrolysis (PEMWE). However, the unsatisfactory stability of RuO 2 and the sluggish proton-coupled electron transfer kinetics of the oxygen evolution reaction (OER) hinder practical application. We report here a fluorine-tuned RuO 2 with terminal fluorine (F ter ) and bridging fluorine (F bri ) sites that successfully tackles the activity-stability paradox faced by Ru-based catalysts. Comprehensive experimental and theoretical studies reveal an unconventional fluorine-assisted deprotonation mechanism by which the proton transfer is decoupled from the electron transfer during the OER. The F ter acts as a proton relay that accelerates deprotonation of intermediates, while F bri contributes to suppressing the lattice oxygen oxidation route. The catalyst exhibited a low overpotential of 191 millivolts at 10 mA per square centimeter and maintained this current density over 2000 h. A practical PEMWE based on this catalyst delivered a current density of 1000 mA per square centimeter at a mere 1.72 V and operated stably over 300 h with a voltage degradation rate of 84 microvolts per hour.

Topics & Concepts

ChemistryDeprotonationOverpotentialInorganic chemistryCatalysisRutheniumOxideElectrolysisElectrolysis of waterElectron transferPhotochemistryAnodeFaraday efficiencyFluorineRuthenium oxideProton-coupled electron transferPolarization (electrochemistry)IridiumOxygenOxygen evolutionStoichiometryMembraneElectrochemistryProtonElectrodeElectrolyteElectrocatalystAmmonia Synthesis and Nitrogen ReductionAdvanced Battery Materials and TechnologiesEnvironmental remediation with nanomaterials
Fluorine Mediates the Deprotonation Pathway over Ruthenium Oxide for Stable Water Electrolysis | Litcius