Litcius/Paper detail

Efficient Surface to Bulk Catalysis in the Reverse Water–Gas Shift Reaction by the FeO <sub> <i>x</i> </sub> /Fe <sub>3</sub> C Catalyst

Zeyu Li, Hao-Xin Liu, Jiahui Wu, Feng Yang, Chao Ma, Wei-Wei Wang, Feng Ryan Wang, Chun-jiang Jia

2026Journal of the American Chemical Society10 citationsDOI

Abstract

Unraveling the dynamic structural evolution and reaction mechanisms of catalysts from the surface to bulk phase is key to advancing the understanding of catalytic origins. Herein, we report that an in situ formed dynamic FeO x /Fe 3 C heterostructure serves as the catalytically active phase, enabling rapid carbon and oxygen atom exchange with reactants under the reverse water–gas shift (RWGS) reaction. On the disordered FeO x (1 ≤ x ≤ 1.5) surface, CO 2 is dissociated into gaseous CO and surface O, while partial CO further decomposes into C that infiltrates into the Fe 3 C lattice. The C atoms from bulk Fe 3 C can combine with the O atoms on FeO x to form CO, allowing Fe 3 C to serve as a reservoir for C atom transfer. Meanwhile, H 2 effectively removes residual surface oxygen to prevent overoxidation. The FeO x /Fe 3 C catalyst, enabled by synergistic surface-to-bulk cycling mechanism, achieves an unprecedented rate of 1.1 × 10 –2 mol/g cat /s at 600 °C in the RWGS reaction, exceeding all previously reported catalysts. This study reveals mechanistic insight into simultaneous catalysis from the surface to the bulk in heterostructured solid catalysts, offering a new perspective on the origin of the exceptional activity of iron-based catalysts in the RWGS reaction.

Topics & Concepts

CatalysisChemistryAtom (system on chip)Water-gas shift reactionHeterojunctionChemical engineeringIn situOxygen atomTransition metalOxygenCarbon fibersPhase (matter)Heterogeneous catalysisNanotechnologyChemical physicsReaction intermediateReaction mechanismSurface (topology)Inorganic chemistrySurface reconstructionPhotochemistryReaction conditionsSynergistic catalysisOxygen evolutionGas phasePhysical chemistryMetalRhodiumCatalytic Processes in Materials ScienceCatalysts for Methane ReformingElectrocatalysts for Energy Conversion