In situ ambient pressure XPS study of Pt/Cu(111) single-atom alloy in catalytically relevant reaction conditions

The presence of multiple reactant gases as well as reaction intermediates in a heterogeneous catalytic reaction results in a complex interaction between different components of the catalyst with each gas, which can alter the surface and chemical state of the catalyst differently than in the presence of an individual gas alone. In this study, we used in situ ambient pressure x-ray photoelectron spectroscopy to study the surface state of Pt/Cu(111) single-atom alloy model system in two catalytically relevant reaction conditions: CO2 hydrogenation and CO oxidation. We found that the activation of CO2 results in the formation of CO, which adsorbs on Pt sites at up to 400 K. In the presence of CO2 and H-2, Pt catalyzes the reverse water-gas shift reaction, which produces more CO and further stabilizes surface Pt atoms at 450 K. On the other hand, in CO oxidation condition, the presence of O-2 results in the formation of a thick Cu2O layer at higher temperatures, and Pt atoms are no longer detected in the surface and subsurface layers. When O-2 is introduced to the sample before CO, the formation of a complete Cu2O layer that covers all Pt atoms occurs immediately at room temperature. However, when CO is introduced at room temperature before O-2, the presence of adsorbed CO on Pt sites stabilizes the surface Pt atoms and prevents the formation of a complete Cu2O layer, thus exposing the Pt atoms in 'holes' in the Cu2O layer.

Automated summary

The study found that different reaction conditions in heterogeneous catalytic reactions lead to the presence of different reactants and products on the surface of Pt/Cu single-atom alloy, causing varying effects on the surface and chemical state of the catalyst.