Efficient spin to charge conversion and spin memory loss mitigation in oriented RuO2 films

Abstract

RuO2, a transition metal oxide, is attracting attention in spintronics for its unique altermagnetic properties, which influence spin currents. Its ability to produce large spin-orbit torques and spin Hall effects is key for energy-efficient magnetic memory and logic devices. Additionally, the tunable thickness and crystallinity of RuO2 thin films optimize torque efficiency for low-power switching. Spin pumping, a versatile method for investigating spin dynamics in RuO2 thin films, has garnered considerable interest because of its straightforward, non-invasive and uncomplicated approach to addressing impedance mismatch and direct measurement of spintronic parameters. Here we present a systematic and detailed analysis on the efficient spin to charge conversion in (110)-oriented RuO2 films with amorphous CoFeB as spin source. The spin Hall angle, and spin diffusion length were estimated to be 0.14 0.01 and 4.58 0.40 nm, respectively. The spin Hall conductivity of 998.89 58.23 · -1 \, cm-1e has been estimated which is theoretically predicted to be of the similar order. The interfacial spin transparency has been achieved to be 90%. We have shown that the spin memory loss at the RuO2/CoFeB interface is 15%, which is very small.