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Oxygen Vacancy-Mediated Hetero-Asymmetrical Dual Active Sites Break the Activity-Stability Trade-Off for Efficient Acidic Water Oxidation

Qiang Gao, Anquan Zhu, Guangzu Liu, Zhiyi Sun, Teng Li, Cui Xu, Xianjun Yin, Feng Li, Wenxing Chen, Zenghe Li, Li-Zhu Wu, Bin Liu

2026Journal of the American Chemical Society14 citationsDOI

Abstract

Regulating the reaction pathway to overcome the activity-stability trade-off of catalysts is significant but remains highly challenging in acidic oxygen evolution reactions (OERs). Herein, we incorporated atomically dispersed Ru into an oxygen vacancy-rich (O vc ) MnO 2– x host through a combination of hydrothermal reaction, argon-plasma bombardment, and isomorphic substitution, resulting in a distinctive catalyst (Ru-AP-MnO 2– x ) featuring O vc -mediated heteroasymmetric dual-active-site Mn–O vc –Ru units. Impressively, the Ru-AP-MnO 2– x catalyst achieved a low overpotential of 233 mV at 100 mA cm –2 and demonstrated an exceptional stability for >5000 h at 10 mA cm –2 in 0.5 M H 2 SO 4 . When used in a proton exchange membrane water electrolyzer (PEMWE), it required a potential of only 1.76 V to reach 3 A cm –2 (surpassing the DOE 2026 target: 1.8 V at 3 A cm –2 ) and operated stably at 1 A cm –2 for up to 2200 h with an extremely low potential decay rate of only 22.3 μV h –1, positioning it among the top-ranked Ru/Ir-based catalysts. Operando characterizations and theoretical calculations demonstrated that enhanced Ru–O covalency and reduced Ru–Mn distance in the unique Mn–O vc –Ru unit enabled a heteroasymmetrical-dual-active-site-assisted lattice oxygen mechanism (HADAS-LOM) for OER, where the *O intermediates transferred from Ru to Mn sites coupled lattice O (O lat ) for rapid O 2 release. Moreover, the bridged O vc increased the electron density at Ru sites to mitigate overoxidation, while synergistic Ru–Mn dual sites allowed O lat around Mn instead of Ru sites to form an *OO intermediate, effectively protecting Ru from dissolution. This work offers a blueprint for engineering O vc and multiple active-site synergy in the design of acid-stable, high-efficiency OER electrocatalysts.

Topics & Concepts

ChemistryCatalysisOverpotentialOxygenOxygen evolutionElectrolysis of waterHydrothermal circulationInorganic chemistryChemical engineeringWater splittingReaction intermediateProton exchange membrane fuel cellElectrolysisElectron transferNanotechnologyActive siteDensity functional theoryPhosphideSynergistic catalysisLattice (music)Hydrothermal synthesisElectrocatalysts for Energy ConversionHybrid Renewable Energy SystemsAmmonia Synthesis and Nitrogen Reduction