Localization of the Higgs mode at the superfluid-Mott glass transition

TL;DR

This study investigates the Higgs mode near the superfluid-Mott glass transition, revealing its localization and unconventional dynamics due to disorder, through Monte Carlo simulations and spectral analysis.

Contribution

It provides the first detailed numerical analysis of the Higgs mode behavior in a disordered quantum phase transition, highlighting its localization and non-critical spectral response.

Findings

Disorder causes the Higgs mode to localize across all dilutions.

Spectral densities show a broad, non-critical response at all energies.

The Higgs mode exhibits momentum-independent dispersion at long wavelengths.

Abstract

The amplitude (Higgs) mode near the two-dimensional superfluid-Mott glass quantum phase transition is studied. We map the Bose-Hubbard Hamiltonian of disordered interacting bosons onto an equivalent classical XY model in (2+1) dimensions and compute the scalar susceptibility of the order parameter amplitude via Monte Carlo simulation. Analytic continuation of the scalar susceptibilities from imaginary to real frequency to obtain the spectral densities is performed by a modified maximum entropy technique. Our results show that the introduction of disorder into the system leads to unconventional dynamical behavior of the Higgs mode that violates naive scaling,despite the underlying thermodynamics of the transition being of conventional power-law type. The computed spectral densities exhibit a broad, non-critical response for all energies, and a momentum-independent dispersion for long-wavelengths, indicating strong evidence for the localization of the Higgs mode for all dilutions.