Entanglement growth during thermalization in holographic systems

Author(s)

Liu, Hong; Suh, Sunok Josephine

Abstract

We derive in detail several universal features in the time evolution of entanglement entropy and other nonlocal observables in quenched holographic systems. The quenches are such that a spatially uniform density of energy is injected at an instant in time, exciting a strongly coupled conformal field theory which eventually equilibrates. Such quench processes are described on the gravity side by the gravitational collapse of a thin shell that results in a black hole. Various nonlocal observables have a unified description in terms of the area of extremal surfaces of different dimensions. In the large distance limit, the evolution of an extremal surface, and thus the corresponding boundary observable, is controlled by the geometry around and inside the event horizon of the black hole, allowing us to identify regimes of pre-local-equilibration quadratic growth, post-local-equilibration linear growth, a memory loss regime, and a saturation regime with behavior resembling those in phase transitions. We also discuss possible bounds on the maximal rate of entanglement growth in relativistic systems.

Date issued

2014-03

URI

http://hdl.handle.net/1721.1/88994

Department

Massachusetts Institute of Technology. Center for Theoretical Physics
Massachusetts Institute of Technology. Department of Physics

Journal

Physical Review D

Publisher

American Physical Society

Citation

Liu, Hong, and S. Josephine Suh. “Entanglement Growth During Thermalization in Holographic Systems.” Phys. Rev. D 89, no. 6 (March 2014). © 2014 American Physical Society

Version: Final published version

ISSN

1550-7998

1550-2368