Realization of a Spin Glass in a two-dimensional van der Waals material

TL;DR

This paper reports the first observation of a spin-glass state in a two-dimensional van der Waals material, Fe3GeTe2, demonstrating that such disordered magnetic states can exist in atomically thin layers.

Contribution

It provides experimental evidence of a 2D spin-glass in a vdW material, expanding understanding of magnetic disorder in low-dimensional systems.

Findings

Spin-glass behavior confirmed by AC susceptibility and dynamic effects

Existence of spin-glass state in single-unit-cell Fe3GeTe2

Spin-glass states can be tuned via intercalation in vdW systems

Abstract

Recent advances in van der Waals (vdW) materials have sparked renewed interest in the impact of dimensionality on magnetic phase transitions. While ordered magnetic phases have been demonstrated to survive in the two-dimensional (2D) limit, the quest for a spin-glass with quenched magnetic disorder in lower dimensions has proven elusive. Here we show evidence of a spin-glass emerging from randomly distributed Fe atoms in Fe3GeTe2, the first time such a state has been reported in a vdW material. AC magnetic susceptibility displays a strong frequency dependence indicative of slow spin dynamics. Additional distinctive phenomena, including ageing, chaos, and memory effects, further substantiate the existence of a glassy state. Remarkably, we find that this state persists even in single-unit-cell thick Fe3GeTe2, thereby confirming the existence of a 2D spin-glass. The formation of spin-glass states via intercalation in vdW systems allows for highly tunable spin-glass states that are otherwise difficult to realize.