# Effective field analysis using the full angular spin-orbit torque   magnetometry dependence

**Authors:** Tomek Schulz, Kyujoon Lee, Benjamin Kr\"uger, Roberto Lo Conte,, Gurucharan V. Karnad, Karin Garcia, Laurent Vila, Berthold Ocker, Dafin\'e, Ravelosona, and Mathias Kl\"aui

arXiv: 1902.04665 · 2019-02-25

## TL;DR

This paper introduces a comprehensive angular analysis method for spin-orbit torque magnetometry, enabling precise determination of effective fields and improving material screening for magnetic quasi-particle dynamics.

## Contribution

It presents a novel approach that incorporates full angular dependence in torque magnetometry, enhancing the accuracy of effective field measurements in spin-orbit torque systems.

## Key findings

- Effective fields can be accurately determined using the proposed method.
- Good agreement between depinning measurements and spin torque magnetometry.
- Method enables rapid screening of materials for quasi-particle dynamics.

## Abstract

Spin-orbit torques promise ultra-efficient magnetization switching used for advanced devices based on emergent quasi-particles such as domain walls and skyrmions. Recently, the spin structure dynamics, materials and systems with tailored spin-orbit torques are being developed. A method, which allows one to detect the acting torques in a given system as a function of the magnetization direction is the torque-magnetometry method based on a higher harmonics analysis of the anomalous Hall-effect. Here we show that the effective fields acting on magnetic domain walls that govern the efficiency of their dynamics require a sophisticated analysis taking into account the full angular dependence of the torques. Using a 1-D model we compared the spin orbit torque efficiencies by depinning measurements and spin torque magnetometry. We show that the effective fields can be accurately determined and we find good agreement. Thus our method allows us now to rapidly screen materials and predict the resulting quasi-particle dynamics.

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Source: https://tomesphere.com/paper/1902.04665