Abstract
Single-atom catalysts have attracted wide attention due to the maximum usage of single atom and the great potential to achieve high activity and selectivity. The oxidation of CO molecules on the single Ir atom embedded graphdiyne (Ir-GDY) has been investigated by using the first-principles calculations. A variety of reaction mechanisms are taken into account and a new pathway is found to catalyze CO oxidation more efficiently on Ir-GDY. A comparison of the reaction energy barrier shows that the CO oxidation likely occurs in the new Eley–Rideal (NER) mechanism rather than the traditional mechanism. In the NER mechanism, the adsorbed O2 molecule is activated by two physisorbed CO molecules thereby formed two CO2 synchronously with the energy barrier of 0.37 eV, as the rate-limiting step. In this reaction, the electrons are transferred from the substrate to the O2 and the CO, which promotes the decomposition of O2. After the C–C bond cleavage, the OOCCOO intermediate dissociates to form two CO2 molecules, in...
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