Thermalization Fronts in the Hubbard-Holstein Model

TL;DR

This study explores the nonequilibrium dynamics and thermalization processes in the Hubbard-Holstein model after a sudden electron-phonon interaction switch-on, revealing a propagating thermalization front in electronic and phononic sectors.

Contribution

It extends the understanding of thermalization fronts to the Hubbard-Holstein model, analyzing the interplay between electron and phonon dynamics using nonequilibrium DMFT.

Findings

Thermalization fronts propagate with the same velocity in both sectors.

Weak quenches show electronic fronts before phononic ones within the simulation window.

Strong coupling leads to simultaneous front development in electrons and phonons.

Abstract

We investigate the nonequilibrium dynamics of the weak-coupling Hubbard-Holstein model after a sudden switch-on of the electron-phonon interaction within nonequilibrium dynamical mean-field theory (DMFT). Using the self-consistent Migdal approximation for the electron-phonon coupling together with second-order perturbation theory for the electron-electron interaction, we show that the relaxation dynamics exhibits a crossover between electron-dominated and phonon-dominated regimes, extending to finite Hubbard interaction the scenario previously identified in the Holstein model. To investigate the microscopic buildup of the thermal state, we analyze the dynamics within the Step-by-Step DMFT framework. In the plane of real time and DMFT iteration number, thermalization is marked by a sharp propagating front. This front appears in electronic observables already for weak quenches within the simulated time window, whereas the phononic sector exhibits a visible front only at sufficiently strong coupling. Thus, at weak coupling the local dispersionless phonons show a delayed onset of front formation, while near and beyond the crossover the front develops on comparable timescales in both the electronic and phononic sectors. Whenever both fronts are resolved, they propagate with the same velocity, showing that thermalization spreads coherently through the coupled electron-phonon system.