# Antisymmetric magnetoresistance in van der Waals   Fe3GeTe2/graphite/Fe3GeTe2 tri-layer heterostructures

**Authors:** Sultan Albarakati, Cheng Tan, Zhong-Jia Chen, James G. Partridge,, Guolin Zheng, Lawrence Farrar, Edwin L.H. Mayes, Matthew R. Field, Changgu, Lee, Yihao Wang, Yiming Xiong, Mingliang Tian, Feixiang Xiang, Alex R., Hamilton, Oleg A. Tretiakov, Dimitrie Culcer, Yu-Jun Zhao, Lan Wang

arXiv: 1904.10588 · 2019-07-23

## TL;DR

This paper reports a novel antisymmetric magnetoresistance effect in vdW heterostructures of Fe3GeTe2 and graphite, revealing new physical mechanisms and potential for advanced spintronic devices.

## Contribution

It demonstrates a unique three-state magnetoresistance in vdW heterostructures, attributed to spin momentum locking at the interface, differing from conventional GMR.

## Key findings

- Discovery of antisymmetric MR in vdW heterostructures
- Identification of three distinct resistance states
- Theoretical explanation involving spin momentum locking

## Abstract

Van der Waals (vdW) ferromagnetic materials are rapidly establishing themselves as effective building blocks for next generation spintronic devices. When layered with non-magnetic vdW materials, such as graphene and/or topological insulators, vdW heterostructures can be assembled (with no requirement for lattice matching) to provide otherwise unattainable device structures and functionalities. We report a hitherto rarely seen antisymmetric magnetoresistance (MR) effect in van der Waals heterostructured Fe3GeTe2/graphite/Fe3GeTe2 devices. Unlike conventional giant magnetoresistance (GMR) which is characterized by two resistance states, the MR in these vdW heterostructures features distinct high, intermediate and low resistance states. This unique characteristic is suggestive of underlying physical mechanisms that differ from those observed before. After theoretical calculations, the three resistance behavior was attributed to a spin momentum locking induced spin polarized current at the graphite/FGT interface. Our work reveals that ferromagnetic heterostructures assembled from vdW materials can exhibit substantially different properties to those exhibited by similar heterostructures grown in vacuum. Hence, it highlights the potential for new physics and new spintronic applications to be discovered using vdW heterostructures.

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Source: https://tomesphere.com/paper/1904.10588