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Tailoring the Near-Surface Environment of Rh Single-Atom Catalysts for Selective CO<sub>2</sub> Hydrogenation

Alexander H. Jenkins, Erin E. Dunphy, Michael F. Toney, Charles B. Musgrave, J. Will Medlin

2023ACS Catalysis24 citationsDOIOpen Access PDF

Abstract

We used a combination of experimental spectroscopies, density functional theory calculations, and CO 2 hydrogenation studies to investigate the effects of modifying single-atom Rh 1 /TiO 2 catalysts with functionalized phosphonic acid monolayers. We found that the deposition of specific amine-functionalized ligands resulted in an ∼8× increase in site-specific CO 2 reduction turnover frequency at 150 °C and a ∼ 2× increase at 250 °C. On-stream stability also improved following ligand deposition. The effect of the modifier on reactivity was highly sensitive to the proximity of the amine functional group to the surface, which was controlled by adjusting the length of the phosphonic acid tail. Furthermore, deposition of alkyl phosphonic acids without an amine functional group resulted in blocked CO 2 adsorption and a near-complete loss of catalytic activity. Infrared spectroscopy studies suggested that the amine group provided binding sites for CO 2 that enabled hydrogenation when the amine was positioned near a Rh 1 site. Phosphonic acid-modified catalysts also exhibited high selectivity to CO over the series product methane; the selectivity effect was traced to modification of the Rh 1 sites to favor CO desorption. Phosphonic acid deposition resulted in 80–90% loss of accessible Rh 1 sites, likely due to blocking by tail groups. However, even with the loss of sites, under low-temperature reaction conditions, the rates of CO 2 hydrogenation were improved with the coatings, indicating that the remaining sites are highly efficient. Organic functionalization of the supports for atomically dispersed catalysts offers the opportunity to precisely control the positioning of functional groups in the vicinity of a well-defined active site, potentially enabling an additional level of control over active site design.

Topics & Concepts

CatalysisAmine gas treatingSelectivityChemistryFunctional groupReactivity (psychology)Surface modificationAlkylInorganic chemistryAdsorptionPhotochemistryOrganic chemistryPhysical chemistryMedicineAlternative medicinePolymerPathologyCatalysts for Methane ReformingCatalytic Processes in Materials ScienceCO2 Reduction Techniques and Catalysts