How do the unique Au/α-FeO interfacial structures determine activity in CO oxidation?

In this study, three α-Fe 2 O 3 crystallites of regular morphology (truncated hexagonal bipyramid, quasi cubic, and hexagonal plate) were prepared in a controllable manner. Based on the (HR)TEM and SEM characterizations, the exposed crystal facets of three α-Fe 2 O 3 crystallites, namely {113}, {214}, {104}, {110}, {012}, and {001}, were carefully identified. Au nanoparticles of ca. 2.0 nm with a narrow particle size distribution were essentially monodispersed on the three α-Fe 2 O 3 substrates through a controlled deposition strategy. In such a way, the Au/α-Fe 2 O 3 interfacial structures with structurally defined oxide substrates and nearly identical Au particle size and morphology have been obtained. The systems allowed us to compare in depth the behaviors of distinct surfaces/interfaces in CO oxidation. The characterization including O 2 /surface hydroxyl-TPD, CO-TPSR, and in situ FTIR clarified the role of the surface oxygen/hydroxyl species in developing crucial intermediates on distinct interfaces. The results demonstrated that the evolution of different intermediates (CO 3 2− and HCO 2 − ) was directly controlled by interfacial features, i.e. , the weakly adsorbed oxygen and surface hydroxyl species as well as the specific Au-Fe 2 O 3 boundary structure, which meaningfully determined CO activation and conversion to CO 2 . The present study provided new insights into the significance of Au/α-Fe 2 O 3 interfacial structures governing the evolution of reaction intermediates in CO oxidation. Unique Au/α-Fe 2 O 3 interfacial structures and the interface-associated intermediates critically determine the activity of CO oxidation.