Spinodal Gravitational Waves

Yago Bea; Jorge Casalderrey-Solana; Thanasis Giannakopoulos; Aron Jansen; Sven Krippendorf; David Mateos; Mikel Sanchez-Garitaonandia; Miguel Zilhão

doi:10.1007/JHEP11(2025)093

Spinodal Gravitational Waves

Yago Bea
, Jorge Casalderrey-Solana
, Thanasis Giannakopoulos
, Aron Jansen
, Sven Krippendorf
, David Mateos
, Mikel Sanchez-Garitaonandia
, Miguel Zilhão

Helsinki Institute of Physics
University of Barcelona
Instituto Superior Técnico
Universität München
Pompeu Fabra University (UPF)
Universidade de Aveiro

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We uncover a new gravitational-wave production mechanism in cosmological, first-order, thermal phase transitions. These are usually assumed to proceed via the nucleation of bubbles of the stable phase inside the metastable phase. However, if the nucleation rate is sufficiently suppressed, then the Universe may supercool all the way down the metastable branch and enter the spinodal region. In this case the transition proceeds via the exponential growth of unstable modes and the subsequent formation, merging and relaxation of phase domains. We use holography to follow the real-time evolution of this process in a strongly coupled, four-dimensional gauge theory and compute the resulting gravitational-wave spectrum. We discuss the possibility that the spinodal dynamics may be preceded by a period of thermal inflation.

langue originale	Anglais
Numéro d'article	93
journal	Journal of High Energy Physics
Volume	2025
Numéro de publication	11
Les DOIs	https://doi.org/10.1007/JHEP11(2025)093
état	Publié - 1 nov. 2025
Modification externe	Oui

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10.1007/JHEP11(2025)093

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abstract = "We uncover a new gravitational-wave production mechanism in cosmological, first-order, thermal phase transitions. These are usually assumed to proceed via the nucleation of bubbles of the stable phase inside the metastable phase. However, if the nucleation rate is sufficiently suppressed, then the Universe may supercool all the way down the metastable branch and enter the spinodal region. In this case the transition proceeds via the exponential growth of unstable modes and the subsequent formation, merging and relaxation of phase domains. We use holography to follow the real-time evolution of this process in a strongly coupled, four-dimensional gauge theory and compute the resulting gravitational-wave spectrum. We discuss the possibility that the spinodal dynamics may be preceded by a period of thermal inflation.",

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AU - Bea, Yago

AU - Casalderrey-Solana, Jorge

AU - Giannakopoulos, Thanasis

AU - Jansen, Aron

AU - Krippendorf, Sven

AU - Mateos, David

AU - Sanchez-Garitaonandia, Mikel

AU - Zilhão, Miguel

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N2 - We uncover a new gravitational-wave production mechanism in cosmological, first-order, thermal phase transitions. These are usually assumed to proceed via the nucleation of bubbles of the stable phase inside the metastable phase. However, if the nucleation rate is sufficiently suppressed, then the Universe may supercool all the way down the metastable branch and enter the spinodal region. In this case the transition proceeds via the exponential growth of unstable modes and the subsequent formation, merging and relaxation of phase domains. We use holography to follow the real-time evolution of this process in a strongly coupled, four-dimensional gauge theory and compute the resulting gravitational-wave spectrum. We discuss the possibility that the spinodal dynamics may be preceded by a period of thermal inflation.

AB - We uncover a new gravitational-wave production mechanism in cosmological, first-order, thermal phase transitions. These are usually assumed to proceed via the nucleation of bubbles of the stable phase inside the metastable phase. However, if the nucleation rate is sufficiently suppressed, then the Universe may supercool all the way down the metastable branch and enter the spinodal region. In this case the transition proceeds via the exponential growth of unstable modes and the subsequent formation, merging and relaxation of phase domains. We use holography to follow the real-time evolution of this process in a strongly coupled, four-dimensional gauge theory and compute the resulting gravitational-wave spectrum. We discuss the possibility that the spinodal dynamics may be preceded by a period of thermal inflation.

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KW - Gauge-Gravity Correspondence

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DO - 10.1007/JHEP11(2025)093

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VL - 2025

JO - Journal of High Energy Physics

JF - Journal of High Energy Physics

IS - 11

M1 - 93

ER -

Spinodal Gravitational Waves

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