The Nuclear Spin Environment in Lateral GaAs Spin Valves

Abstract

The spin degree of freedom in solids offers opportunities beyond charge-based electronics and is actively investigated for both spintronics and quantum computation. However, the interplay of these spins with their native environment can give rise to detrimental effects such as spin relaxation and decoherence. Here, we use an all-electrical, lateral GaAs spin valve to manipulate and investigate the inherent nuclear spin system. Hanle satellites are used to determine the nuclear spin relaxation rates for the previously unexplored temperature range down to 100 mK, giving T1 times as long as 3 hours. Despite metallic temperature dependence of resistivity, the observed relaxation rates show a sub-linear temperature dependence. This contrasts the Korringa relaxation mechanism observed in metals but is not inconsistent with hyperfine-mediated relaxation in a disordered, interacting conductor not far from the metal-insulator transition. We discuss possible relaxation mechanisms and further investigate inhomogeneities in the nuclear spin polarization.