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
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.