Abstract
The valorization of carbon oxides on metal/metal oxide catalysts has been extensively investigated because of its ecological and economical relevance. However, the ambiguity surrounding the active sites in such catalysts hampers their rational development. Here, in situ infrared spectroscopy in combination with isotope labeling revealed that CO molecules adsorbed on Ti3+ and Cu+ interfacial sites in Cu/TiO2 gave two disparate carbonyl peaks. Monitoring each of these peaks under various conditions enabled tracking the adsorption of CO, CO2, H2, and H2O molecules on the surface. At room temperature, CO was initially adsorbed on the oxygen vacancies to produce a high frequency CO peak, Ti3+−CO. Competitive adsorption of water molecules on the oxygen vacancies eventually promoted CO migration to copper sites to produce a low-frequency CO peak. In comparison, the presence of gaseous CO2 inhibits such migration by competitive adsorption on the copper sites. At temperatures necessary to drive CO2 and CO hydrogenation reactions, oxygen vacancies can still bind CO molecules, and H2 spilled-over from copper also competed for adsorption on such sites. Our spectroscopic observations demonstrate the existence of bifunctional active sites in which the metal sites catalyze CO2 dissociation whereas oxygen vacancies bind and activate CO molecules.
Highlights
The valorization of carbon oxides on metal/metal oxide catalysts has been extensively investigated because of its ecological and economical relevance
The ability of CO to identify surface sites and to assess their activity was widely implemented in CO oxidation, to develop catalysts for automotive emissions control[34–36], it is less explored in COx hydrogenation
In situ diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS) was employed to follow CO molecules as they bind to two disparate surface sites on Cu/TiO2 at room temperature
Summary
The valorization of carbon oxides on metal/metal oxide catalysts has been extensively investigated because of its ecological and economical relevance. In situ diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS) was employed to follow CO molecules as they bind to two disparate surface sites on Cu/TiO2 at room temperature The behavior of both sites was tracked, via monitoring carbonyl peak intensity and position, as isotopically labeled 13CO2 molecules dissociate and H2O is introduced, and as conditions are changed to in situ hydrogenation conditions. Examining the disparities in their behavior under these conditions revealed novel information that dictated an assignment different from what was proposed previously in the literature Such observations and discussion provide insights on the bifunctional role played by the metal sites and the interface during COx hydrogenation reaction
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
