The impact of dynamic nuclear polarization on non-local spin valve and inverse spin Hall Hanle measurements in n-GaAs

Non-local spin valve (NLSV) and inverse spin Hall (ISHE) Hanle measurements are important tools to probe spin-transport parameters such as the spin lifetime and spin Hall angle. We carried out such measurements on Fe/n-GaAs heterostructure samples with varying doping (3x10¹⁶ to 7x10¹⁶ cm^-3) and at temperatures from 2 K to 110 K. The Hanle curves are very sensitive to the hyperfine field generated by dynamic nuclear polarization (DNP). Below a threshold temperature that depends on doping, the hyperfine field leads to distortion of the Hanle line-shapes for both NLSV and ISHE measurements and can enhance the ISHE signal by one order of magnitude. We have developed a pulsed-current technique which utilizes the vast difference between electron and nuclear spin relaxation time scales (about ns and s respectively) to eliminate the impact of the steady-state hyperfine field, and the obtained Hanle curves then match expectations based on simple drift-diffusion models. We will discuss the extracted spin lifetime and spin Hall angle, numerical modeling of the Hanle curves and the role of the hyperfine field in enhancing the apparent spin Hall signal.