Keldysh field theory of a driven dissipative Mott insulator: nonequilibrium response and phase transitions

TL;DR

This paper develops a large-N Keldysh field theory to analyze nonequilibrium transport, phase transitions, and relaxation dynamics in a driven dissipative Mott insulator under an electric field, revealing unique transient and steady-state behaviors.

Contribution

The authors introduce a novel large-N Keldysh field theory framework for nonequilibrium strongly correlated systems, specifically applied to a dissipative Mott insulator under electric field, highlighting new relaxation and transport phenomena.

Findings

Transient Bloch oscillations decay as inverse square law in time.

Steady state current governed by large-distance cotunneling.

Low-field DC current follows a Landau-Zener-Schwinger form, differing from dissipation-free case.

Abstract

Understanding strongly correlated systems driven out of equilibrium is a challenging task necessitating the simultaneous treatment of quantum mechanics,dynamical constraints and strong interactions. A Mott insulator subjected to a uniform and static electric field is prototypical, raising key questions such as the fate of Bloch oscillations with increasing correlation strength, the approach to a steady state DC transport regime and the role of dissipation in it, and electric field driven phase transitions. We develop here an effective large-N Keldysh field theory for studying nonequilibrium transport in a regular one-dimensional dissipative Mott insulator system subjected to a uniform electric field. Upon abruptly turning on the electric field (a quench), a transient oscillatory current response reminiscent of Bloch oscillations is found. In the regime of small tunneling conductance the amplitude of these oscillations, over a large time window, decreases as an inverse square power-law in time, ultimately going over to an exponential decay beyond a large characteristic time that increases with N. Such a relaxation to a steady state DC response is absent in the dissipation free Hubbard chain at half filling. The steady state current at small fields is governed by large distance cotunneling, a process absent in the equilibrium counterpart. The low-field DC current has a Landau-Zener-Schwinger form but qualitatively differs from the expression for pair-production probability for the dissipation free counterpart. The breakdown of perturbation theory in the Mott phase possibly signals a nonequilibrium phase transition to a metallic phase. Our study sheds light on the approach of a driven, dissipative strongly correlated system to a nonequilibrium steady state and also provides a general analytic microscopic framework for understanding other nonequilibrium phenomena in these systems.