# Interface-driven unusual anomalous Hall effect in MnxGa/Pt bilayers: No   correlation with chiral spin structures

**Authors:** Kangkang Meng, Lijun Zhu, Zhenhu Jin, Enke Liu, Xupeng Zhao, Iftikhar, Ahmed Malik, Zhenguo Fu, Yong Wu, Jun Miao, Xiaoguang Xu, Jinxing Zhang,, Jianhua Zhao, Yong Jiang

arXiv: 1901.05646 · 2019-11-20

## TL;DR

This study reports an unusual anomalous Hall effect in MnxGa/Pt bilayers that mimics topological Hall signals but occurs without chiral spin structures, highlighting the importance of interface properties.

## Contribution

It demonstrates that the anomalous Hall features can arise from interface effects rather than chiral spin structures, challenging previous interpretations of Hall signals.

## Key findings

- UAHE observed without chiral spin structures
- Hall features not correlated with magnetic bubbles
- Interface properties drive the UAHE

## Abstract

The effects of spin-orbit coupling and symmetry breaking at the interface between a ferromagnet and heavy metal are particularly important for spin-based information storage and computation. Recent discoveries suggest they can create chiral spin structures (e.g. skyrmions), which have often been identified through the appearance of the bump/dip features of Hall signals, the so-called topological Hall effect (THE). In this work, however, we have present an unusual anomalous Hall effect (UAHE) in MnxGa/Pt bilayers and demonstrated that the features extremely similar to THE can be generated without involving any chiral spin structures. The low temperature magnetic force microscopy has been used to explore the magnetic field-dependent behavior of spin structures, and the UAHE as a function of magnetic field does not peak near the maximal density of magnetic bubbles. The results unambiguously evidence that the UAHE in MnxGa/Pt bilayers shows no correlation with chiral spin structures but is driven by the modified interfacial properties. The bump/dip features of Hall signals cannot be taken as an unambiguous signature for the emergence of chiral spin structures, and a wealth of underlying and interesting physics need explored.

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Source: https://tomesphere.com/paper/1901.05646