# Quantitative Study on Current-Induced Effect in an Antiferromagnet   Insulator/Pt Bilayer Film

**Authors:** Pengxiang Zhang, Joseph Finley, Taqiyyah Safi, Luqiao Liu

arXiv: 1907.00314 · 2019-12-18

## TL;DR

This study investigates the current-induced effects in an antiferromagnetic insulator/Pt bilayer, demonstrating control of the Neel vector and distinguishing magnetic from non-magnetic contributions to magnetoresistance.

## Contribution

It introduces a method to control and calibrate current-induced magnetic dynamics in antiferromagnetic insulators using an external field and distinguishes magnetic effects from resistive switching.

## Key findings

- Neel vector can be controlled with a moderate external field.
- Resistive switching can mimic magnetoresistance changes without magnetic origin.
- Current-induced effects are quantitatively characterized in Pt/aFe2O3 bilayers.

## Abstract

Quantitative investigation on the current-induced torque in antiferromagnets represents a great challenge, due to the lack of an independent method for controlling N\'eel vectors. Here by utilizing an antiferromagnetic insulator with Dzyaloshinskii-Moriya interaction, {\alpha}-Fe2O3, we show that the N\'eel vector can be controlled with a moderate external field, which is further utilized to calibrate the current-induced magnetic dynamics. We find that the current-induced magnetoresistance change in antiferromagnets can be complicated by resistive switching that does not have a magnetic origin. By excluding non-magnetic switching and comparing the current-induced dynamics with the field-induced one, we determine the nature and magnitude of current-induced effects in Pt/{\alpha}-Fe2O3 bilayer films.

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Source: https://tomesphere.com/paper/1907.00314