Structural, magnetic, electric, dielectric, and thermodynamic properties of multiferroic GeV4S8

TL;DR

This study comprehensively characterizes the multiferroic properties of GeV4S8, revealing complex interactions between structural, magnetic, electric, and thermodynamic phenomena driven by orbital and spin orderings.

Contribution

It provides detailed experimental insights into the coupling of structural, electronic, and magnetic properties in GeV4S8, highlighting the interplay of orbital, polar, and magnetic orders.

Findings

Observation of orbital and ferroelectric transitions around 30 K.

Evidence of antiferromagnetic order below 14 K.

Strong coupling between lattice distortions and magnetic order.

Abstract

The lacunar spinel GeV4S8 undergoes orbital and ferroelectric ordering at the Jahn-Teller transition around 30 K and exhibits antiferromagnetic order below about 14 K. In addition to this orbitally driven ferroelectricity, lacunar spinels are an interesting material class, as the vanadium ions form V4 clusters representing stable molecular entities with a common electron distribution and a well-defined level scheme of molecular states resulting in a unique spin state per V4 molecule. Here we report detailed x-ray, magnetic susceptibility, electrical resistivity, heat capacity, thermal expansion, and dielectric results to characterize the structural, electric, dielectric, magnetic, and thermodynamic properties of this interesting material, which also exhibits strong electronic correlations. From the magnetic susceptibility, we determine a negative Curie-Weiss temperature, indicative for antiferromagnetic exchange and a paramagnetic moment close to a spin S = 1 of the V4 molecular clusters. The low-temperature heat capacity provides experimental evidence for gapped magnon excitations. From the entropy release, we conclude about strong correlations between magnetic order and lattice distortions. In addition, the observed anomalies at the phase transitions also indicate strong coupling between structural and electronic degrees of freedom. Utilizing dielectric spectroscopy, we find the onset of significant dispersion effects at the polar Jahn-Teller transition. The dispersion becomes fully suppressed again with the onset of spin order. In addition, the temperature dependencies of dielectric constant and specific heat possibly indicate a sequential appearance of orbital and polar order.