Crossing a large-N phase transition at finite volume

Yago Bea; Oscar J.C. Dias; Thanasis Giannakopoulos; David Mateos; Mikel Sanchez-Garitaonandia; Jorge E. Santos; Miguel Zilhão

doi:10.1007/JHEP02(2021)061

Crossing a large-N phase transition at finite volume

Yago Bea, Oscar J.C. Dias, Thanasis Giannakopoulos, David Mateos, Mikel Sanchez-Garitaonandia, Jorge E. Santos, Miguel Zilhão

Research output: Contribution to journal › Article › peer-review

Abstract

The existence of phase-separated states is an essential feature of infinite-volume systems with a thermal, first-order phase transition. At energies between those at which the phase transition takes place, equilibrium homogeneous states are either metastable or suffer from a spinodal instability. In this range the stable states are inhomogeneous, phase-separated states. We use holography to investigate how this picture is modified at finite volume in a strongly coupled, four-dimensional gauge theory. We work in the planar limit, N → ∞, which ensures that we remain in the thermodynamic limit. We uncover a rich set of inhomogeneous states dual to lumpy black branes on the gravity side, as well as first- and second-order phase transitions between them. We establish their local (in)stability properties and show that fully non-linear time evolution in the bulk takes unstable states to stable ones.

Original language	English
Article number	61
Journal	Journal of High Energy Physics
Volume	2021
Issue number	2
DOIs	https://doi.org/10.1007/JHEP02(2021)061
Publication status	Published - 1 Feb 2021
Externally published	Yes

Keywords

AdS-CFT Correspondence
Black Holes
Gauge-gravity correspondence

Access to Document

10.1007/JHEP02(2021)061

Cite this

@article{3cb60fc77fcb42008334562b0c60bd50,

title = "Crossing a large-N phase transition at finite volume",

abstract = "The existence of phase-separated states is an essential feature of infinite-volume systems with a thermal, first-order phase transition. At energies between those at which the phase transition takes place, equilibrium homogeneous states are either metastable or suffer from a spinodal instability. In this range the stable states are inhomogeneous, phase-separated states. We use holography to investigate how this picture is modified at finite volume in a strongly coupled, four-dimensional gauge theory. We work in the planar limit, N → ∞, which ensures that we remain in the thermodynamic limit. We uncover a rich set of inhomogeneous states dual to lumpy black branes on the gravity side, as well as first- and second-order phase transitions between them. We establish their local (in)stability properties and show that fully non-linear time evolution in the bulk takes unstable states to stable ones.",

keywords = "AdS-CFT Correspondence, Black Holes, Gauge-gravity correspondence",

author = "Yago Bea and Dias, \{Oscar J.C.\} and Thanasis Giannakopoulos and David Mateos and Mikel Sanchez-Garitaonandia and Santos, \{Jorge E.\} and Miguel Zilh{\~a}o",

note = "Publisher Copyright: {\textcopyright} 2021, The Author(s).",

year = "2021",

month = feb,

day = "1",

doi = "10.1007/JHEP02(2021)061",

language = "English",

volume = "2021",

journal = "Journal of High Energy Physics",

issn = "1126-6708",

number = "2",

}

TY - JOUR

T1 - Crossing a large-N phase transition at finite volume

AU - Bea, Yago

AU - Dias, Oscar J.C.

AU - Giannakopoulos, Thanasis

AU - Mateos, David

AU - Sanchez-Garitaonandia, Mikel

AU - Santos, Jorge E.

AU - Zilhão, Miguel

PY - 2021/2/1

Y1 - 2021/2/1

N2 - The existence of phase-separated states is an essential feature of infinite-volume systems with a thermal, first-order phase transition. At energies between those at which the phase transition takes place, equilibrium homogeneous states are either metastable or suffer from a spinodal instability. In this range the stable states are inhomogeneous, phase-separated states. We use holography to investigate how this picture is modified at finite volume in a strongly coupled, four-dimensional gauge theory. We work in the planar limit, N → ∞, which ensures that we remain in the thermodynamic limit. We uncover a rich set of inhomogeneous states dual to lumpy black branes on the gravity side, as well as first- and second-order phase transitions between them. We establish their local (in)stability properties and show that fully non-linear time evolution in the bulk takes unstable states to stable ones.

AB - The existence of phase-separated states is an essential feature of infinite-volume systems with a thermal, first-order phase transition. At energies between those at which the phase transition takes place, equilibrium homogeneous states are either metastable or suffer from a spinodal instability. In this range the stable states are inhomogeneous, phase-separated states. We use holography to investigate how this picture is modified at finite volume in a strongly coupled, four-dimensional gauge theory. We work in the planar limit, N → ∞, which ensures that we remain in the thermodynamic limit. We uncover a rich set of inhomogeneous states dual to lumpy black branes on the gravity side, as well as first- and second-order phase transitions between them. We establish their local (in)stability properties and show that fully non-linear time evolution in the bulk takes unstable states to stable ones.

KW - AdS-CFT Correspondence

KW - Black Holes

KW - Gauge-gravity correspondence

UR - https://www.scopus.com/pages/publications/85104462582

U2 - 10.1007/JHEP02(2021)061

DO - 10.1007/JHEP02(2021)061

M3 - Article

AN - SCOPUS:85104462582

SN - 1126-6708

VL - 2021

JO - Journal of High Energy Physics

JF - Journal of High Energy Physics

IS - 2

M1 - 61

ER -

Crossing a large-N phase transition at finite volume

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this