Universality of Dissipation across Holographic Interfaces

TL;DR

This paper investigates dissipation and relaxation in a holographic interface conformal field theory, revealing a universal measure of interface-induced suppression of relaxation that is independent of coupling details.

Contribution

It introduces a universal interface observable, crelax, derived from quasinormal modes, characterizing dissipation in holographic interfaces, inspired by spin chain results.

Findings

crelax is independent of coupling details

crelax acts as a universal measure of dissipation

quasinormal modes determine relaxation properties

Abstract

Motivated by recent results in spin chains we study dissipation and relaxation in a two-dimensional holographic interface conformal field theory (ICFT) in which degrees of freedom on one side of the interface are coupled to an external bath, while the other side remains isolated. In the bulk description this setup is realized by gluing a supersymmetric Janus geometry to a BTZ black hole region, with the coupling implemented through a double-trace deformation. We determine the quasinormal modes in the bulk by solving the double-trace matching conditions of the system and bath. The lowest imaginary part of the modes defines a Liouvillian gap, and following earlier work in spin chains we introduce the dimensionless ratio crelax as a measure of interface-induced suppression of relaxation. Numerically we find that, crelax is independent of coupling details to the bath. It is a strong candidate for a universal interface observable characterizing dissipation and relaxation across the interface.