Calculation of current-induced torque from spin continuity equation

TL;DR

This paper introduces a new formulation for calculating current-induced spin torque using the spin continuity equation, avoiding traditional assumptions and enabling first-principles material estimations.

Contribution

It presents a novel approach to compute spin torques without assuming local spin-charge separation, applicable to real materials via first-principles calculations.

Findings

Derived analytical expressions for spin torques and β terms.

Demonstrated the formalism in the adiabatic limit of the s-d model.

Connected spin relaxation mechanisms to torque generation.

Abstract

Current-induced torque is formulated based on the spin continuity equation. The formulation does not rely on the assumption of separation of local spin and charge degrees of freedom, in contrast to approaches based on the $s$-$d$ model or mean-field approximation of itinerant ferromagnetism. This new method would be thus useful for the estimation of torques in actual materials by first-principles calculations. As an example, the formalism is applied to the adiabatic limit of the $s$-$d$ model in order to obtain the analytical expression for torques and corresponding $\beta$ terms arising from spin relaxation due to spin-flip scattering and spin-orbit interaction.