Toward 100% Spin-Orbit Torque Efficiency with High Spin-Orbital Hall Conductivity Pt-Cr Alloys

Abstract: 5d transition metal Pt is the canonical spin Hall material for efficient generation of spin-orbit torques (SOTs) in Pt/ferromagnetic layer (FM) heterostructures. However, for a long while with tremendous engineering endeavors, the damping-like SOT efficiencies (${\xi}{DL}$) of Pt and Pt alloys have still been limited to ${\xi}{DL}$<0.5. Here we present that with proper alloying elements, particularly 3d transition metals V and Cr, a high spin-orbital Hall conductivity (${\sigma}{SH}{\sim}6.5{\times}10^{5}({\hbar}/2e){\Omega}^{-1}{\cdot} m^{-1}$) can be developed. Especially for the Cr-doped case, an extremely high ${\xi}{DL}{\sim}0.9$ in a Pt${0.69}$Cr${0.31}$/Co device can be achieved with a moderate Pt${0.69}$Cr${0.31}$ resistivity of ${\rho}{xx}{\sim}133 {\mu}{\Omega}{\cdot}cm$. A low critical SOT-driven switching current density of $J{c}{\sim}3.2{\times}10^{6} A{\cdot}cm^{-2}$ is also demonstrated. The damping constant (${\alpha}$) of Pt${0.69}$Cr${0.31}$/FM structure is also found to be reduced to 0.052 from the pure Pt/FM case of 0.078. The overall high ${\sigma}{SH}$, giant ${\xi}{DL}$, moderate ${\rho}_{xx}$, and reduced ${\alpha}$ of such a Pt-Cr/FM heterostructure makes it promising for versatile extremely low power consumption SOT memory applications.