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Electron-Deficient Ru <sup>δ+</sup> Sites Coupled with Lattice Oxygen at Ru/BaTiO <sub>3</sub> Interfaces Enable Efficient Photothermal Methane Dry Reforming

Bo Su, Ke Tang, Junjian Cai, Xiahui Lin, Wandong Xing, Kunlong Liu, Xue Lu, Yidong Hou, Wee‐Jun Ong, Sibo Wang

2026ACS Catalysis12 citationsDOI

Abstract

Solar-driven dry reforming of methane (DRM) represents a promising pathway for syngas production, yet its practical application is challenged by insufficient activity and rapid deactivation. Here, we report a Ru/BaTiO 3 catalyst with interfacial electron-deficient Ru δ+ sites and dynamic lattice oxygens for efficient photothermal DRM. Under light irradiation, the catalyst delivers H 2 and CO production rates of 68.43 and 85.18 mol g Ru –1 h –1, a methane turnover frequency of 1.08 s –1, a light-to-chemical energy efficiency of 14.2%, and stable operation over 100 h. Combined experimental and theoretical studies reveal that interband electronic transition-induced electrons migrate from Ru nanoparticles to BaTiO 3, enriching Ru δ+ sites that drive stepwise C–H bond cleavage in CH 4 . Meanwhile, lattice oxygens from BaTiO 3 oxidize CH* to CHO*, generating oxygen vacancies that convert CO 2 into CO and are refilled by the incorporation of an O*, sustaining a closed redox cycle. This dual mechanism of light-triggered electronic modulation and lattice oxygen participation launches a paradigm for optimizing DRM pathways. The findings highlight the critical role of nonplasmonic metal–support interfaces in solar-driven CH 4 /CO 2 conversion.

Topics & Concepts

CatalysisCarbon dioxide reformingMethaneSyngasOxygenLattice (music)Chemical engineeringRedoxMaterials scienceChemical physicsNanoparticlePhotochemistryChemistryAnaerobic oxidation of methaneAdsorptionNanotechnologyElectronic effectInorganic chemistryHeterogeneous catalysisBond cleavageSteam reformingOxygen evolutionPhysical chemistryPhotothermal therapyAdvanced Photocatalysis TechniquesCatalysts for Methane ReformingCO2 Reduction Techniques and Catalysts