Far-from-equilibrium energy flow and entanglement entropy

TL;DR

This paper investigates the far-from-equilibrium energy flow and entanglement entropy in strongly coupled systems using holography, revealing universal properties of quenching and steady state formation.

Contribution

It provides a detailed holographic analysis of energy transport and entanglement dynamics during far-from-equilibrium processes in strongly coupled systems.

Findings

Identification of steady state formation during energy flow

Universal properties of the quenching process

Time evolution of holographic entanglement entropy

Abstract

The time evolution of the energy transport triggered in a strongly coupled system by a temperature gradient is holographically related to the evolution of an asymptotically AdS black brane. We study the far-from-equilibrium properties of such a system by using the AdS/CFT correspondence. In particular, we describe the appearance of a steady state, and study the information flow by computing the time evolution of the holographic entanglement entropy. Some universal properties of the quenching process are presented.