Electron-Magnon Coupling Mediated Magnetotransport in Antiferromagnetic van der Waals Heterostructure

TL;DR

This study investigates electron-magnon interactions in FLG/FePS extsubscript{3} heterostructures, revealing temperature-dependent magnetic and transport phenomena, including negative magnetoresistance and magnetodielectric effects linked to magnon-phonon hybridization.

Contribution

It provides new insights into interfacial electron-magnon coupling effects on magnetotransport and dielectric properties in van der Waals heterostructures.

Findings

Magnon mode softens below 40 K in FePS extsubscript{3}

Negative magnetoresistance persists up to 100 K in FLG/FePS extsubscript{3}

Coupling strength decreases with fewer layers, suppressing negative MR

Abstract

Electron-magnon coupling reveals key insights into the interfacial properties between non-magnetic metals and magnetic insulators, influencing charge transport and spin dynamics. Here, we present temperature-dependent Raman spectroscopy and magneto-transport measurements of few-layer graphene (FLG)/antiferromagnetic FePS\(_3\) heterostructures. The magnon mode in FePS\(_3\) softens below 40 K, and effective magnon stiffness decreases with cooling. Magnetotransport measurements show that FLG exhibits negative magnetoresistance (MR) in the heterostructure at low fields (\(\pm 0.2 \, \text{T}\)), persisting up to 100 K; beyond this, MR transitions to positive. Notably, as layer thickness decreases, the coupling strength at the interface reduces, leading to a suppression of negative MR. Additionally, magnetodielectric measurements in the FLG/FePS\(_3\)/FLG heterostructure show an upturn at temperatures significantly below ($T_\text{N}$), suggesting a role for the magnon mode in capacitance, as indicated by hybridization between magnon and phonon bands in pristine FePS\(_3\) \textit{via} magnetoelastic coupling.