Domain wall propagation by spin-orbit torques in in-plane magnetized systems

TL;DR

This paper investigates how damping-like spin-orbit torque influences domain wall motion in in-plane magnetized systems, revealing that it can efficiently drive vortex walls and enhance domain wall manipulation for spintronic applications.

Contribution

It provides an analytical and simulation-based analysis of DL SOT effects on domain walls, highlighting the role of DMI and geometrical confinement, and challenges simplified models of SOT effects.

Findings

DL SOT drives vortex domain walls effectively.

Transverse domain walls require DMI to propagate.

SOT can outperform spin-transfer torque in domain wall motion.

Abstract

The effect of damping-like spin-orbit torque (DL SOT) on magnetic domain walls (DWs) in in-plane magnetised soft tracks is studied analytically and with micromagnetic simulations. We find that DL SOT drives vortex DWs, whereas transverse DWs, the other typical DW structure in soft tracks, propagate only if the Dzyaloshinskii-Moriya interaction (DMI) is present. The SOT drive can add to, and be more efficient than, spin-transfer torque (STT), and so may greatly benefit applications that require in-plane DWs. Our analysis based on the Thiele equation shows that the driving force arises from a cycloidal distortion of the DW structure caused by geometrical confinement or DMI. This distortion is higher, and the SOT more efficient, in narrower, thinner tracks. These results show that the effects of SOT cannot be understood by simply considering the effective field at the center of the structure, an ill-founded but often-used estimation. We also show that the relative magnitude of STT and DL SOT can be determined by comparing the motion of different vortex DW structures in the same track.