Near-Barrierless CO Oxidation Using Phosphotungstic Acid-Supported Single-Atom Catalysts.

Efficient CO oxidation at ambient or low temperatures is essential for environmental purification and selective CO oxidation in H 2 , yet achieving this remains a challenge with current methodologies. In this research, we extensively evaluated the catalytic performance of phosphotungstic acid (PTA)-supported 11 M 1 /PTA single-atom catalysts (SACs) using density functional theory calculations across both gas phase and 12 common solvents. The Rh 1 /PTA, Pd 1 /PTA, and Pt 1 /PTA systems exhibit moderate CO adsorption energies, facilitating the feasibility of oxygen vacancy formation. Remarkably, the Pd 1 /PTA and Pt 1 /PTA catalysts exhibited negligible energy barriers and demonstrated exceptionally high catalytic rates, with values reaching up to (1 × 10 10 ) 11 , markedly exceeding the threshold for room temperature reactions, set at 6.55 × 10 8 . This phenomenon is attributed to a transition from the high-energy barrier processes of oxygen dissociation in O 2 and N-O bond dissociation in N 2 O to the more efficient dissociation of H 2 O 2 . Orbital analysis and charge variations at metal sites throughout the reaction process provide deeper insights into the role of the three metal catalytic sites in CO activation. Our findings not only reveal key aspects of SACs in facilitating CO oxidation at low temperatures but also provide valuable insights for future catalytic reaction mechanism studies and environmental applications.