▎ 摘　　要

A study is carried out which investigates the effects of the mono-vacancies of boron (VB) and nitrogen (VN) and the co-vacancies of nitrogen (N), and boron (B) on the energetics and the structural, electronic, and magnetic properties of an h-BN/graphene heterobilayer using first-principles calculations within the framework of the density functional theory (DFT). The heterobilayer is modelled using the periodic slab scheme. In the present case, a 4 x 4-(h-BN) monolayer is coupled to a 4 x 4-graphene monolayer, with a mismatch of 1.40%. In this coupling, the surface of interest is the 4 x 4-(h-BN) monolayer; the 4 x 4-graphene only represents the substrate that supports the 4 x 4-(h-BN) monolayer. From the calculations of the energy of formation of the 4 x 4-(h-BN)/4 x 4-graphene heterobilayer, with and without defects, it is established that, in both cases, the heterobilayers are energetically stable, from which it is inferred that these heterobilayers can be grown in the experiment. The formation of a mono-vacancy of boron (1 V-B), a mono-vacancy of nitrogen (1 V-N), and co-vacancies of boron and nitrogen (V-BN) induce, on the structural level: (a) for 1 V-B, a contraction n of the B-N bond lengths of similar to 2.46% and a slight change in the interfacial distance D (similar to 0.096%) with respect to the heterobilayer free of defects (FD) are observed; (b) for 1 V-N, a slight contraction of the B-N of bond lengths of similar to 0.67% and an approach between the h-BN monolayer and the graphene of similar to 3.83% with respect to the FD heterobilayer are observed; (c) for V-BN, it can be seen that the N-N and B-B bond lengths (in the 1 V-B and 1 V-N regions, respectively) undergo an increase of similar to 2.00% and a decrease of similar to 3.83%, respectively. The calculations of the Lowdin charge for the FD heterobilayer and for those with defects (1 V-B, 1 V-N, and V-BN) show that the inclusion of this type of defect induces significant changes in the Lowdin charge redistribution of the neighboring atoms of VB and VN, causing chemically active regions that could favor the interaction of the heterobilayer with external atoms and/or molecules. On the basis of an analysis of the densities of states and the band structures, it is established that the heterobilayer with 1 V-B and V-BN take on a half-metallic and magnetic behavior. Due to all of these properties, the FD heterobilayer and those with 1 V-B, 1 V-N, and V-BN are candidates for possible adsorbent materials and possible materials that could be used for different spintronic applications.