Nitrogen and boron coordinated single-atom catalysts for low-temperature CO/NO oxidations

In order to explore the intrinsic properties of single-atom (SA) catalysts, the different kinds of coordinated atoms (typically B-x and N-y) within graphene (BxNy-graphene, x + y = 1-3) can be used to regulate the stability and electronic structure of center metal SAs (BxNy-graphene-SAs) by density functional theory (DFT) calculations. It is found that the SA Co anchored at single vacancy graphene (SV-graphene-Co), B-1-graphene-Co and N-1-graphene-Co configurations exhibit higher stability than others. The amount of charge transfer between coordinated BxNy and nearest-neighbor carbon atoms can effectively modulate the adsorption stabilities, electronic structures and magnetic properties of central Co atom and reactive gases. Compared to the SV-graphene-Co sheet, the formation of BxNy-graphene sheets can promote the adsorption capabilities for NO and CO; further, the NO and CO oxidation reactions through the Eley-Rideal (ER) and Langmuir-Hinshelwood (LH) mechanisms are comparably investigated. Among these different ratios of coordinated BxNy atoms, the B-1-graphene-Co, N-1-graphene-Co and B1N1-graphene-Co sheets exhibit good stability and show excellent catalytic activity (<0.5 eV). Therefore, theoretical calculations can provide an in-depth understanding of the structure-performance relationship between coordinated B/N atoms and intrinsic activity of SA catalysts (SACs), which is essential for the precise design of graphene-based SACs and their potential applications.

Automated summary

The use of density functional theory calculations to study the intrinsic properties of single-atom (SA) catalysts revealed that the coordinated atoms within graphene can effectively modulate the stability and electronic structure of central metal SAs, impacting their catalytic activity and adsorption capabilities. Furthermore, theoretical calculations provide insights into the structure-performance relationship essential for the precise design of graphene-based SA catalysts and their potential applications.