Hydrogen diffusion in GaAs1-xNx

Hydrogen (or deuterium) incorporation in dilute nitride semiconductors modifies dramatically the electronic and structural properties of the crystal through the creation of nitrogen-hydrogen complexes. In this work, we investigate how the formation and dissociation of such complexes rule the diffusion of deuterium in GaAs1-xNx. The concentration depth profile of deuterium is determined by secondary ion mass spectrometry under a wide range of experimental conditions that comprise different N concentrations (x=0.09%, 0.40%, 0.70%, and 1.5%) and D irradiation temperatures (T-D=200, 250, 300 and 350 degrees C). The experimental data are successfully reproduced by a diffusion model in the presence of strong D trapping. In particular, the deuterium diffusion and capture rate coefficients are determined, and a minimum decay length of the deuterium forefront is found at low T-D (< 250 degrees C) and high x (>0.7%). These parameters set the experimental conditions within which a nanostructuring of the physical properties of GaAs1-xNx is attainable.