Tuning the magnetic properties of the spin-split antiferromagnet MnTe through pressure

TL;DR

This study investigates how applying pressure alters the magnetic properties of MnTe, revealing increased Neel temperature and reduced magnetic moments, which could enhance spintronic device performance.

Contribution

It demonstrates that pressure can tune MnTe's magnetic properties by modifying exchange interactions and orbital hybridization, a novel approach for spintronic material optimization.

Findings

Pressure increases Neel temperature of MnTe.

Pressure decreases the ordered magnetic moment.

Magnetic exchange interactions are strengthened under pressure.

Abstract

The hexagonal antiferromagnet MnTe has attracted enormous interest as a prototypical example of a spin-compensated magnet in which the combination of crystal and spin symmetries lifts the spin degeneracy of the electron bands without the need for spin-orbit coupling, a phenomenon called non-relativistic spin splitting (NRSS). Subgroups of NRSS are determined by the specific spin-interconverting symmetry that connects the two opposite-spin sublattices. In MnTe, this symmetry is rotation, leading to the subgroup with spin splitting away from the Brillouin zone center, often called altermagnetism. MnTe also has the largest spontaneous magnetovolume effect of any known antiferromagnet, implying strong coupling between the magnetic moment and volume. This magnetostructural coupling offers a potential knob for tuning the spin-splitting properties of MnTe. Here, we use neutron diffraction with $\textit{in situ}$ applied pressure to determine the effects of pressure on the magnetic properties of MnTe and further explore this magnetostructural coupling. We find that applying pressure significantly increases the N\'eel temperature but decreases the ordered magnetic moment. We explain this as a consequence of strengthened magnetic exchange interactions under pressure, resulting in higher $T_\mathrm{N}$, with a simultaneous reduction of the local moment of individual Mn atoms, described here via density functional theory. This reflects the increased orbital hybridization and electron delocalization with pressure. These results show that the magnetic properties of MnTe can be controlled by pressure, opening the door to improved properties for spintronic applications through tuning via physical or chemical pressure.