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. 2025 Oct 13;64(42):e202515905.
doi: 10.1002/anie.202515905. Epub 2025 Aug 25.

Mn3O4/Pt Oxide-on-Metal Inverse Catalyst Facilitates Hydrogen Spillover for CO2 Hydrogenation Reaction

Xiaoyu Liang #  1   2 Cui Dong #  1   3 Le Lin #  4 Yingjie Wang  1   5 Youyuanhe Yang  1   2 Rankun Zhang  1 Dongqing Wang  1 Xi Cheng  1   2 Rentao Mu  1 Qiang Fu  1
Affiliations

Mn3O4/Pt Oxide-on-Metal Inverse Catalyst Facilitates Hydrogen Spillover for CO2 Hydrogenation Reaction

Xiaoyu Liang et al. Angew Chem Int Ed Engl. .

Abstract

Hydrogen spillover, the migration of metal-activated hydrogen species across support surfaces, is key for many H-related reactions. However, questions remain about how the metal/oxide interfaces affect hydrogen spillover and hydrogenation reaction. Here, we construct Mn3O4-on-Pt(111) (Mn3O4/Pt(111)) inverse catalyst and Pt clusters-on-Mn3O4 (Pt/Mn3O4) catalyst, and image hydrogen spillover behavior using high-pressure scanning tunneling microscopy. We find that the onset H2 partial pressure for hydrogen spillover is two orders of magnitude lower at Mn3O4/Pt(111) than at Pt/Mn3O4. This structural promotion effect was leveraged to synthesize MnOx/Pt/C inverse catalyst by depositing MnOx on Pt nanoparticles, which exhibits a 1.8-fold higher CO2 conversion compared to conventional Pt/MnOx/C catalyst during CO2 hydrogenation. Theoretical calculations reveal that the inverse catalysts promote hydrogen spillover via weaker H adsorption and a more favorable transition-state geometry at interfacial Pt sites, particularly along the Pt─Mn─O pathway. The Pt/Mn3O4 interfaces feature strong H binding on Ptδ⁺ and high H diffusion barriers, which can be partially mitigated by CO co-adsorption. These findings demonstrate that inverse structure offers both electronic and geometric advantages at the interfaces, enabling efficient hydrogen spillover for hydrogenation reactions.

Keywords: Heterogeneous catalysis; Hydrogen spillover; Hydrogenation; Inverse catalyst, Metal‐oxide interface.

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