Quantum critical dynamics in two-dimensional transverse Ising model

Abstract

In the vicinity of the quantum critical point(QCP), thermodynamic properties diverge toward zero temperature governed by universal exponents. Although this fact is well known, how it is reflected in quantum dynamics has not been addressed. As an ideal experimental platform to test the issue, we consider an organic Mott insulator whose dielectric degrees of freedom, a quantum electric dipole, is described by the transverse Ising model on a triangular lattice that has a QCP. We track the Glauber-type dynamics of the model by constructing a kinetic protocol based on the quantum Monte Carlo method. The dynamical susceptibility takes the form of the Debye function and shows a significant peak-narrowing in approaching a QCP due to the divergence of the relaxation timescale. It resembles the anomaly of dielectric constants observed in the organic materials appa-ET 2 X dimer Mott insulating phase, indicating that the material is very near the ferroelectric QCP.