Hydrodynamics of phase transition fronts and the speed of sound in the
  plasma

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Abstract

The growth of bubbles in cosmological first-order phase transitions involves nontrivial hydrodynamics. For that reason, the study of the propagation of phase transition fronts often requires several approximations. A frequently used approximation consists in describing the two phases as being composed only of radiation and vacuum energy (the so-called bag equation of state). We show that, in realistic models, the speed of sound in the low-temperature phase is generally smaller than that of radiation, and we study the hydrodynamics in such a situation. We find in particular that a new kind of hydrodynamical solution may be possible, which does not arise in the bag model. We obtain analytic results for the efficiency of the transfer of latent heat to bulk motions of the plasma, as a function of the speed of sound in each phase.

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Is Open Access

On Bubble Growth and Droplet Decay in Cosmological Phase Transitions

M. Laine, H. Kurki-Suonio (1995)

We study spherically symmetric bubble growth and droplet decay in first order cosmological phase transitions, using a numerical code including both the complete hydrodynamics of the problem and a phenomenological model for the microscopic entropy producing mechanism at the phase transition surface. The small-scale effects of finite wall width and surface tension are thus consistently incorporated. We verify the existence of the different hydrodynamical growth modes proposed recently and investigate the problem of a decaying quark droplet in the QCD phase transition. We find that the decaying droplet leaves behind no rarefaction wave, so that any baryon number inhomogeneity generated previously should survive the decay.

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Journal

Publication date Created: 14 October 2014

Publication date Updated: 2015-03-06

Article

DOI: 10.1016/j.nuclphysb.2014.12.008

ArXiV ID: 1410.3875

SO-VID: c1939739-668c-4abd-954e-5efcaa9cd157

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http://arxiv.org/licenses/nonexclusive-distrib/1.0/

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Comments 44 pages, 19 figures. v2: some comments and references added. v3: Some discussions and a figure added. Results unchanged. Matches published version

Categories hep-ph astro-ph.CO

ScienceOpen disciplines: Cosmology & Extragalactic astrophysics,High energy & Particle physics

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ScienceOpen disciplines: Cosmology & Extragalactic astrophysics, High energy & Particle physics