Charge dynamics at nitrogen impurities and nitrogen-vacancy centers in diamond

Abstract

The nitrogen-vacancy (NV) center in diamond is the prototype quantum defect that enables a variety of diamond-based quantum technologies. However, charge-state instability and spectral diffusion, often induced by substitutional nitrogen impurities (N C), remain key challenges for device performance. Here, we employ first-principles density functional theory calculations to quantitatively investigate nonradiative carrier capture processes mediated by multiphonon emission at both the NV center and the N C impurity. For relevant cases, we also compute the rates of radiative and thermal emission processes. For N C0 N C-, we obtain an electron capture coefficient of 2.2 × 10-8 cm3s-1 at 300 K. Both the magnitude and temperature dependence are in excellent agreement with experimentally measured capture cross sections. Electron capture at N C+ is even faster, with a capture coefficient of 1.0 × 10-4 cm3s-1 at 300 K. For the NV center, we find that carrier capture rates involving only the ground states of NV0 and NV- are negligibly slow. However, capture into the excited states (NV0* and NV-*) is significantly faster. In particular, the capture coefficient for the hole capture process NV- NV0* is as large as 1.8 × 10-7 cm3s-1 and largely temperature-independent. Hole capture at NV- will thus occur via nonradiative capture into an excited state of NV0 followed by fast radiative decay to the NV0 ground state. Similarly, electron capture at NV0 will occur via the NV0 NV-* NV- pathway, but with a lower nonradiative capture coefficient (2.1 × 10-9 cm3s-1 at 300 K). Our calculated capture coefficients and rates provide essential information for analyzing charge-state dynamics.