A Theoretical Investigation on CO Oxidation by Single‐Atom Catalysts M(1)/γ‐Al(2)O(3) (M=Pd, Fe, Co, and Ni)

Single‐atom catalysts have attracted much interest recently because of their excellent stability, high catalytic activity, and remarkable atom efficiency. Inspired by the recent experimental discovery of a highly efficient single‐atom catalyst Pd(1)/γ‐Al(2)O(3), we conducted a comprehensive DFT study on geometries, stabilities and CO oxidation catalytic activities of M(1)/γ‐Al(2)O(3) (M=Pd, Fe, Co, and Ni) by using slab‐model. One of the most important results here is that Ni(1)/Al(2)O(3) catalyst exhibits higher activity in CO oxidation than Pd(1)/Al(2)O(3). The CO oxidation occurs through the Mars van Krevelen mechanism, the rate‐determining step of which is the generation of CO(2) from CO through abstraction of surface oxygen. The projected density of states (PDOS) of 2p orbitals of the surface O, the structure of CO‐adsorbed surface, charge polarization of CO and charge transfer from CO to surface are important factors for these catalysts. Although the binding energies of Fe and Co with Al(2)O(3) are very large, those of Pd and Ni are small, indicating that the neighboring O atom is not strongly bound to Pd and Ni, which leads to an enhancement of the reactivity of the O atom toward CO. The metal oxidation state is suggested to be one of the crucial factors for the observed catalytic activity.