Deep-level structure of the spin-active recombination center in dilute nitrides
Abstract
A Gallium interstitial defect (Gai) is thought to be responsible for the spectacular spin-dependent recombination (SDR) in GaAs1-xNx dilute nitride semiconductors. Current understanding associates this defect with two in-gap levels corresponding to the (+/0) and (++/+) charge-state transitions. Using a spin-sensitive photo-induced current transient spectroscopy, the in-gap electronic structure of a x = 0.021 alloy is revealed. The (+/0) state lies ≈ 0.27 eV below the conduction band edge, and an anomalous, negative activation energy reveals the presence of not one but two other states in the gap. The observations are consistent with a (++/+) state ≈ 0.19 eV above the valence band edge, and a hitherto ignored, (+++/++) state ≈ 25 meV above the valence band edge. These observations can inform efforts to better model the SDR and the Gai defect's local chemical environment.
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