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Role of Interfacial Water in Improving the Activity and Stability of Lattice‐Oxygen‐Mediated Acidic Oxygen Evolution on RuO 2
Author(s) -
Wu Liqing,
Huang Wenxia,
Li Dongyang,
Zhao Bingbing,
Zhou Haiqing,
Luo Wei
Publication year - 2025
Publication title -
angewandte chemie international edition
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 5.831
H-Index - 550
eISSN - 1521-3773
pISSN - 1433-7851
DOI - 10.1002/anie.202420848
Subject(s) - oxygen evolution , oxygen , x ray photoelectron spectroscopy , electrolyte , dissociation (chemistry) , catalysis , chemistry , water splitting , chemical engineering , chemical physics , electrochemistry , electrode , organic chemistry , engineering , photocatalysis
Abstract Although RuO 2 ‐based electrocatalysts have been widely studied for acidic oxygen evolution reaction (OER), triggering the conventional adsorbate evolution mechanism to suppress kinetically favorable lattice oxygen mechanism (LOM) pathway at the expense of activity is the state‐of‐the‐art strategy. To date, approaches to simultaneously achieve remarkable activity and stability of RuO 2 ‐based electrocatalysts through the kinetically favorable LOM pathway toward acidic OER are still elusive. Herein, we report that RuS 0.45 O x catalyst with the synergetic regulation of asymmetric S–Ru–O microstructure and Ru–SO 4 local environments can simultaneously boost the lattice‐oxygen‐mediated OER activity and stability under acidic electrolyte. Experimental results, including operando attenuated total reflectance surface‐enhanced infrared absorption spectroscopy, operando X‐ray photoelectron spectroscopy, and theoretical studies, indicate the dynamic evolution of interfacial water structure from hydrogen‐bond water to free‐H 2 O on the surface of RuS 0.45 O x . The generated continuous free‐H 2 O‐enriched local environment is in favor of accelerating the sluggish kinetics of interfacial water dissociation and facilitating the replenishment of lattice oxygen vacancies generated during the lattice‐oxygen‐mediated OER process, thereby significantly enhancing the stability. Consequently, the obtained RuS 0.45 O x displays remarkable acidic OER performance with 160 mV to reach 10 mA cm −2 , and robust stability with negligible activity decay over 500 h at 100 mA cm −2 .

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