# Structural, magnetic, and electrical properties of collinear   antiferromagnetic heteroepitaxy cubic Mn$_3$Ga thin films

**Authors:** Hyun-Woo Bang, Woosuk Yoo, Chungman Kim, Sunghun Lee, Jiyeong Gu,, Yunchang Park, Kyujoon Lee, Myung-Hwa Jung

arXiv: 1901.09524 · 2019-10-30

## TL;DR

This study reports the first experimental verification of cubic antiferromagnetic Mn$_3$Ga thin films, detailing their structural, magnetic, and electrical properties and comparing them with ferrimagnetic tetragonal Mn$_3$Ga.

## Contribution

It provides experimental evidence of cubic Mn$_3$Ga's antiferromagnetic phase and characterizes its properties, which were previously only theoretically predicted.

## Key findings

- C-Mn$_3$Ga is hetero-epitaxially grown on MgO with a cubic structure.
- C-Mn$_3$Ga exhibits an antiferromagnetic transition at 400 K.
- C-Mn$_3$Ga shows higher electrical resistivity than T-Mn$_3$Ga.

## Abstract

Although a cubic phase of Mn$_3$Ga with an antiferromagnetic order has been theoretically predicted, it has not been experimentally verified in a bulk or film form. Here, we report the structural, magnetic, and electrical properties of antiferromagnetic cubic Mn$_3$Ga (C-Mn$_3$Ga) thin films, in comparison with ferrimagnetic tetragonal Mn$_3$Ga (T-Mn3Ga). The structural analyses reveal that C-Mn$_3$Ga is hetero-epitaxially grown on MgO substrate with the Cu$_3$Au-type cubic structure, which transforms to T-Mn$_3$Ga as the RF sputtering power increases. The magnetic and magnetotransport data show the antiferromagnetic transition at T$_N$ = 400 K for C-Mn$_3$Ga and the ferrimagnetic transition at T$_C$ = 820 K for T-Mn$_3$Ga. Furthermore, we find that the antiferromagnetic C-Mn$_3$Ga exhibits a higher electrical resistivity than the ferrimagnetic T-Mn$_3$Ga, which can be understood by spin-dependent scattering mechanism.

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Source: https://tomesphere.com/paper/1901.09524