First-principles characterization of native defects and oxygen impurities in GaAs

We present an investigation of native point defects and oxygen impurities in gallium arsenide (GaAs) using hybrid density-functional calculations. Defects are characterized by their structural, electronic, and optical properties. Dominant native defects are Ga antisites (Ga$_{\rm As}$), As antisites (As$_{\rm Ga}$), and/or Ga vacancies ($V_{\rm Ga}$) in which As$_{\rm Ga}$ and $V_{\rm Ga}$ are charge-compensating defects under As-rich conditions. On the basis of the calculated defect transition levels, the isolated As$_{\rm Ga}$ may be identified with the EL2 center reported in experiments. The defect, however, has a negligible nonradiative electron capture cross section and thus cannot be the "main electron trap" as commonly believed. We find that GaAs can have multiple O-related defect centers when prepared under As-rich conditions. The quasi-substitutional O impurity (O$_{\rm As}$) and its complex with two As$_{\rm Ga}$ defects (O$_{\rm As}$-2As$_{\rm Ga}$) have a metastable and paramagnetic middle (neutral) charge state. These two defects have large nonradiative electron capture cross sections and can be effective recombination centers.