Bethe-Salpeter Equation calculations of nitrogen-vacancy defects in diamond

Doped diamonds are of significant fundamental, technological, and commercial interest. For example, boron doping leads to a blue coloration at low concentration and superconductivity at high concentration. Similarly nitrogen doping can cause a variety of colors in diamond. Nitrogen-vacancy defects are also promising as quantum-computing qubits. Theoretical Bethe-Salpeter Equation (BSE) simulations of boron-doped diamonds have been found to give optical absorption spectra in good agreement with their observed blue coloration. In contrast, nitrogen defects are more complex, due in part to a plethora of possible N-defect conformations. Here we present a theoretical study of several neutral, isolated, N-defect conformations that combines ab initio DFT calculations for relaxed 64-atom unit cells together with first principles GW/BSE calculations of their optical spectra. Spectral results are compared with available experimental data, and the effects of absorption are simulated for realistic rendered diamonds.