Unraveling the Intermediate Reaction Complexes and Critical Role of Support-Derived Oxygen Atoms in CO Oxidation on Single-Atom Pt/CeO2

CeO2-supported Pt single-atom catalysts have been extensively studied due to their relevance in automobile emission control and for the fundamental understanding of CeO2-based catalysts. Though CeO2-supported Pt nanoparticles are often more active than their single-atom counterparts, the former could easily redisperse to Pt single atom under oxidizing diesel conditions. Therefore, to maximize the reactivity of every Pt atom, it is important to fully understand the reaction mechanism of CeO2-supported Pt single atoms. Here, we report a CO oxidation study on a Pt/CeO2 single-atom catalyst, where we can account for all of the neighbors using in situ and operando spectroscopy techniques and microcalorimetric measurements. Coupled with density functional theory calculations, we present a comprehensive picture of the dynamics of the surface species, the role of surface intermediates, and explain the observed reaction kinetics. We started with a catalyst containing exclusively single atoms and used in situ/operando spectroscopy to provide evidence for their stability during the reaction and to identify the Pt1 complexes before and during the reaction and their binding to CO. The results reveal that in the precatalyst, Pt is present as Pt(O)(4) on the CeO2(111) step edge sites, but during CO oxidation, we find that two Pt-1 complexes coexist, representing two states of the same active site in the reaction cycle. The dominant state/complex remains Pt(O)(4), which adsorbs CO very weakly as shown by CO microcalorimetry. The second, minority state/complex, Pt(CO)(O)(3) is generated through the reaction of Pt(O)(4) with CO, and CO is bound strongly to Pt-1. Labile oxygen adatoms from the CeO2 surface play a major role in the regeneration of Pt(O)(4) either directly from Pt(O)(3) or by reaction with the strongly adsorbed CO in Pt(CO)(O)(3). We show that the formation of an oxygen vacancy and generation of a labile O* are not barrierless, which explains the long lifetime of Pt(CO)(O)(3) and its detectability despite being a minority complex. The results help to develop a comprehensive view of the dynamic evolution of Pt-1 complexes along the reaction cycle and provide mechanistic insights to guide the design of Pt-based single-atom catalysts.

Automated summary

CeO2-supported Pt single-atom catalysts are important for automobile emission control and understanding catalyst mechanisms. In CO oxidation studies, Pt-1 complexes exhibit different states during reaction cycles, with Pt(O)(4) as the dominant form and Pt(CO)(O)(3) as a minority complex. The presence of labile oxygen adatoms from the CeO2 surface plays a crucial role in the regeneration of Pt complexes during the reaction.