Oxygen-Bearing Defects in Graphene-Supported M–N–C Single-Atom Catalysts: A Hidden Determinant of Catalytic Performance
Yiheng Huang, Hui Hu, Chenhui Wang, Chenhui Wang, Xuanhao Yuan, Xingyue Wu, Zhengping Qiao, Yan Li, Chengxin Wang, Chengxin Wang
Abstract
In the study of M–N–C single-atom catalysts (SACs), a series of unresolved issues point to the structural role of inevitable oxygen-bearing defects in the carbon lattice beyond the MN 4 moieties. Through explaining experimental observations on the enhanced oxygen reduction reaction (ORR) activity of hydrogenated Fe–N–C SACs, we demonstrated the necessity of incorporating such oxygen-bearing defects in modeling frameworks. Furthermore, the sp 3 -hybridized carbon atoms near these defects readily adsorb hydrogen atoms and exhibit competitive ORR performance. Therefore, this discovery also offers an alternative strategy for increasing the density of active sites. Subsequently, we performed systematic calculations to revisit the mechanism of reduction reactions of small molecules (O 2, CO 2, and N 2 ) over Fe–N–C SACs. The varying synergistic effects between different oxygen-bearing defect configurations and the FeN 4 moiety lead to distinct magnetic moments of Fe centers, unraveling the origin of the previously observed discrepancies in ORR performances of such catalysts. Furthermore, we established a unified modeling strategy based on oxygen-bearing defects and extended it to elucidate the experimentally observed enhancement in the catalytic activity for F-doped NiN 4 and Cl-doped ZnN 4 SACs. Overall, our calculations address three long-standing challenges in the field of M–N–C SACs: (1) discrepancies in reported catalytic performances despite identical MN 4 active sites, (2) low active site density, and (3) the absence of standardized modeling strategies for functionalized M–N–C SACs. This study provides a deep understanding of the structure–property relationship in graphene-supported SACs, emphasizing the crucial role of the inevitable oxygen-bearing defects in electrochemical reactions.