Ensemble spin relaxation of shallow donor qubits in ZnO

Abstract

We present an experimental and theoretical study of the longitudinal electron spin relaxation (T1) of shallow donors in the direct band-gap semiconductor ZnO. T1 is measured via resonant excitation of the Ga donor-bound exciton. T1 exhibits an inverse-power dependence on magnetic field T1 B-n, with 4≤ n≤ 5, over a field range of 1.75 T to 7 T. We derive an analytic expression for the donor spin-relaxation rate due to spin-orbit (admixture mechanism) and electron-phonon (piezoelectric) coupling for the wurtzite crystal symmetry. Excellent quantitative agreement is found between experiment and theory suggesting the admixture spin-orbit mechanism is the dominant contribution to T1 in the measured magnetic field range. Temperature and excitation-energy dependent measurements indicate a donor density dependent interaction may contribute to small deviations between experiment and theory. The longest T1 measured is 480 ms at 1.75 T with increasing T1 at smaller fields theoretically expected. This work highlights the extremely long longitudinal spin-relaxation time for ZnO donors due to their small spin-orbit coupling.