Field-tuned ferroquadrupolar quantum phase transition in the insulator TmVO$_{4}$

TL;DR

This study investigates the ferroquadrupolar quantum phase transition in TmVO$_{4}$, revealing how magnetic field tuning and lattice interactions influence quantum critical behavior and deviations from classical models.

Contribution

It demonstrates the field-tuned quantum criticality of ferroquadrupolar order in TmVO$_{4}$ and highlights the role of lattice coupling in modifying critical behavior.

Findings

Quantum critical point accessible via magnetic field.

Deviations from semi-classical behavior near the critical point.

Lattice coupling influences critical scaling and fluctuations.

Abstract

We report results of low-temperature heat capacity, magnetocaloric effect and neutron diffraction measurements of TmVO$_{4}$, an insulator that undergoes a continuous ferroquadrupolar phase transition associated with local partially-filled $4f$ orbitals of the thulium (Tm$^{3+}$) ions. The ferroquadrupolar transition, a realization of Ising nematicity, can be tuned to a quantum critical point using a magnetic field oriented along the $c$-axis of the tetragonal crystal lattice, which acts as an effective transverse field for the Ising-nematic order. In small magnetic fields, the thermal phase transition can be well-described using a semi-classical mean field treatment of the transverse field Ising model. However, in higher magnetic fields, closer to the field-tuned quantum phase transition, subtle deviations from this semi-classical behavior are observed due to quantum fluctuations. Although the phase transition is driven by the local $4f$ degrees of freedom, the crystal lattice still plays a crucial role, both in terms of mediating the interactions between the local quadrupoles, and in determining the critical scaling exponents, even though the phase transition itself can be described via mean field. In particular, bilinear coupling of the nematic order parameter to acoustic phonons changes the spatial and temporal fluctuations of the former in a fundamental way, resulting in different critical behavior of the nematic transverse-field Ising model as compared to the usual case of the magnetic transverse-field Ising model. Our results establish TmVO$_{4}$ as a model material, and electronic nematicity as a paradigmatic example, for quantum criticality in insulators.