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Main Authors: Dorsch, Gláuber C., Konstandin, Thomas, Perboni, Enrico, Pinto, Daniel A.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2412.09266
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author Dorsch, Gláuber C.
Konstandin, Thomas
Perboni, Enrico
Pinto, Daniel A.
author_facet Dorsch, Gláuber C.
Konstandin, Thomas
Perboni, Enrico
Pinto, Daniel A.
contents Cosmological phase transitions can give rise to intriguing phenomena, such as baryogenesis or a stochastic gravitational wave background, due to nucleation and percolation of vacuum bubbles in the primordial plasma. A key parameter for predicting these relics is the bubble wall velocity, whose computation relies on solving the Boltzmann equations of the various species along the bubble profile. Recently it has been shown that an unphysical singularity emerges if one assumes these local quantities to be described as small fluctuations over a constant equilibrium background. In this work we solve this issue by including the spatial dependence of the background into the fluid Ansatz. This leads to a modification of the Boltzmann equation, and all terms that would give rise to a singularity now vanish. We recalculate the different contributions to the counter-pressure of the plasma on the expanding wall, and discuss their relative importance. The Standard Model with a low cutoff is chosen as benchmark model and the results are shown for different values of the cutoff scale $Λ$. In this setup, deflagration solutions are found for almost all the values of $Λ$ considered, while detonations are found only for some restricted corner of the parameter space.
format Preprint
id arxiv_https___arxiv_org_abs_2412_09266
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Non-singular solutions to the Boltzmann equation with a fluid Ansatz
Dorsch, Gláuber C.
Konstandin, Thomas
Perboni, Enrico
Pinto, Daniel A.
High Energy Physics - Phenomenology
Cosmological phase transitions can give rise to intriguing phenomena, such as baryogenesis or a stochastic gravitational wave background, due to nucleation and percolation of vacuum bubbles in the primordial plasma. A key parameter for predicting these relics is the bubble wall velocity, whose computation relies on solving the Boltzmann equations of the various species along the bubble profile. Recently it has been shown that an unphysical singularity emerges if one assumes these local quantities to be described as small fluctuations over a constant equilibrium background. In this work we solve this issue by including the spatial dependence of the background into the fluid Ansatz. This leads to a modification of the Boltzmann equation, and all terms that would give rise to a singularity now vanish. We recalculate the different contributions to the counter-pressure of the plasma on the expanding wall, and discuss their relative importance. The Standard Model with a low cutoff is chosen as benchmark model and the results are shown for different values of the cutoff scale $Λ$. In this setup, deflagration solutions are found for almost all the values of $Λ$ considered, while detonations are found only for some restricted corner of the parameter space.
title Non-singular solutions to the Boltzmann equation with a fluid Ansatz
topic High Energy Physics - Phenomenology
url https://arxiv.org/abs/2412.09266