Pressure-induced magnetic properties of quasi-2D Cr2Si2Te6 and Mn3Si2Te6

TL;DR

This study investigates how applying hydrostatic pressure affects the magnetic properties of two quasi-2D layered materials, Cr2Si2Te6 and Mn3Si2Te6, revealing contrasting trends in their magnetic transition temperatures and underlying exchange interactions.

Contribution

It provides new experimental and theoretical insights into pressure-induced magnetic behavior in quasi-2D layered materials, highlighting differences in exchange coupling responses.

Findings

Pressure decreases ferromagnetic transition temperature in CST.

Pressure increases ferrimagnetic transition temperature in MST.

Exchange coupling in MST is strongly pressure-dependent, unlike in CST.

Abstract

Recently, the pressure has been used as external stimuli to induce structural and magnetic phase transitions in many layered quantum materials whose layers are linked by van der Waals forces. Such materials with weakly held layers allow relatively easy manipulation of the superexchange mechanism and lead to novel magnetic behavior. Using the hydrostatic pressure as a disorderless means to manipulate the interlayer coupling, we applied pressure on two quasi-2D sister compounds, namely, Cr2Si2Te6 (CST) and Mn3Si2Te6 (MST), up to ~1 GPa. Magnetic property measurements with the application of pressure revealed that the ferromagnetic transition temperature decreases in CST while the opposite trend occurs for the ferrimagnet MST. In MST, the magnetization decreases with the increase in the pressure, and such trend is not clearly noticed in CST, within the pressure range studied. Theoretical calculations showed the overall pressure effect on layer separation, bond angle, and exchange coupling, strongly influencing the change in subsequent magnetic characteristics. Exchange coupling in Mn3Si2Te6 is strongly frustrated and the first nearest neighbor interaction is the most dominant of the components with the strongest pressure dependence. Whereas, in Cr2Si2Te6, the exchange coupling parameters exhibit very little dependence on the pressure. This combined experimental and theoretical work has the potential to expand to other relevant quantum materials.