Pressure-enhanced ferromagnetism in layered CrSiTe3 flakes

TL;DR

This study demonstrates that applying pressure to layered CrSiTe3 flakes significantly enhances their ferromagnetic properties, increasing the Curie temperature and coercive field, which could advance nanoscale spintronics and pressure-sensitive magnetic devices.

Contribution

The paper reveals pressure-induced transition from soft to hard ferromagnetism and increases in Curie temperature in CrSiTe3, supported by experimental measurements and density functional theory calculations.

Findings

Curie temperature increases from ~36 K to ~138 K under pressure.

Coercive field dramatically increases with pressure, indicating stronger ferromagnetism.

Pressure enhances exchange interactions and magneto-crystalline anisotropy.

Abstract

The research on van der Waals (vdW) layered ferromagnets have promoted the development of nanoscale spintronics and applications. However, low-temperature ferromagnetic properties of these materials greatly hinder their applications. Here, we report pressure-enhanced ferromagnetic behaviours in layered CrSiTe3 flakes revealed by high-pressure magnetic circular dichroism (MCD) measurement. At ambient pressure, CrSiTe3 undergoes a paramagnetic-to-ferromagnetic phase transition at 32.8 K, with a negligible hysteresis loop, indicating a soft ferromagnetic behaviour. Under 4.6 GPa pressure, the soft ferromagnet changes into hard one, signalled by a rectangular hysteretic loop with remnant magnetization at zero field. Interestingly, with further increasing pressure, the coercive field (H_c) dramatically increases from 0.02 T at 4.6 GPa to 0.17 T at 7.8 GPa, and the Curie temperature (T_c^h: the temperature for closing the hysteresis loop) also increases from ~36 K at 4.6 GPa to ~138 K at 7.8 GPa. The influences of pressure on exchange interactions are further investigated by density functional theory calculations, which reveal that the in-plane nearest-neighbor exchange interaction and magneto-crystalline anisotropy increase simultaneously as pressure increases, leading to increased H_c and T_c^h in experiments. The effective interaction between magnetic couplings and external pressure offers new opportunities for both searching room-temperature layered ferromagnets and designing pressure-sensitive magnetic functional devices.