Spin transfer torques generated by the anomalous Hall effect and anisotropic magnetoresistance

TL;DR

This paper demonstrates how the anomalous Hall effect and anisotropic magnetoresistance can generate spin-transfer torques to switch magnetization and move domain walls, offering a controllable alternative to the spin Hall effect.

Contribution

It introduces a drift-diffusion model for spin currents from these effects, enabling control of spin orientation via magnetization direction, and shows potential for efficient magnetic switching.

Findings

Effective switching of perpendicular magnetized layers demonstrated.

Control of spin transfer torque via magnetization orientation.

Predicted low critical current densities for switching.

Abstract

Spin-orbit coupling in ferromagnets gives rise to the anomalous Hall effect and the anisotropic magnetoresistance, both of which can be used to create spin-transfer torques in a similar manner as the spin Hall effect. In this paper we show how these effects can be used to reliably switch perpendicularly magnetized layers and to move domain walls. A drift-diffusion treatment of the anomalous Hall effect and the anisotropic magnetoresistance describes the spin currents that flow in directions perpendicular to the electric field. In systems with two ferromagnetic layers separated by a spacer layer, an in-plane electric field cause spin currents to be injected from one layer into the other, creating spin transfer torques. Unlike the related spin Hall effect in non-magnetic materials, the anomalous Hall effect and the anisotropic magnetoresistance allow control of the orientation of the injected spins, and hence torques, by changing the direction of the magnetization in the injecting layer. The torques on one layer show a rich angular dependence as a function of the orientation of the magnetization in the other layer. The control of the torques afforded by changing the orientation of the magnetization in a fixed layer makes it possible to reliably switch a perpendicularly magnetized free layer. Our calculated critical current densities for a representative CoFe/Cu/FePt structure show that the switching can be efficient for appropriate material choices. Similarly, control of the magnetization direction can drive domain wall motion, as shown for NiFe/Cu/NiFe structures.