Formation and excitation energies as well charge transition levels are determined for the substitutional nitrogen (N${}_{\mathrm{s}}$), the vacancy (V), and related point defects (NV, NVH, N${}_2$, N${}_2$V, and V${}_2$) by screened nonlocal hybrid density functional supercell plane wave calculations in bulk diamond. In addition, the activation energy for V and NV diffusion is calculated. We find good agreement between theory and experiment for the previously well-established data and predict missing ones. Based on the calculated properties of these defects, the formation of the negatively charged NV center is studied, because it is a prominent candidate for application in quantum information processing and for nanosensors. Our results indicate that NV defects are predominantly created directly by irradiation, while simultaneously produced vacancies will form V${}_2$ pairs during postirradiation annealing. Divacancies may pin the Fermi level, making the NV defects neutral.

• Received 18 September 2013
• Corrected 21 February 2014

DOI:https://doi.org/10.1103/PhysRevB.89.075203