Abstract
Engineering a bimetallic system with complementary chemical properties can be an effective way of tuning catalytic activity. In this work, CO oxidation on CeO2(111)-supported Pd-based bimetallic nanorods was investigated using density functional theory calculations corrected by on-site Coulomb interactions. We studied a series of CeO2(111)-supported Pd-based bimetallic nanorods (Pd–X, where X = Ag, Au, Cu, Pt, Rh, Ru) and found that Pd–Ag/CeO2 and Pd–Cu/CeO2 are the two systems where the binding sites of CO and O2 are distinct; that is, in these two systems, CO and O2 do not compete for the same binding sites. An analysis of the CO oxidation mechanisms suggests that the Pd–Ag/CeO2 system is more effective for catalyzing CO oxidation as compared to Pd–Cu/CeO2 because both CeO2 lattice oxygen atoms and adsorbed oxygen molecules at Ag sites can oxidize CO with low energy barriers. Both the Pd–Ag and Pd–CeO2 interfaces in Pd–Ag/CeO2 were found to play important roles in CO oxidation. The Pd–Ag interface, whic...
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