Model-independent energy budget for LISA

Giese, Felix; Schmitz, Kai Ruven; van de Vis, Jorinde; Konstandin, Thomas

Preprint

PUBDB-2020-04189

Model-independent energy budget for LISA

Giese, F.DESY* ; Konstandin, T.DESY* ; Schmitz, K. R.DESY* ; van de Vis, J. (Corresponding author)DESY*

2020

1-30 (2020) [10.3204/PUBDB-2020-04189]

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Please use a persistent id in citations: doi:10.3204/PUBDB-2020-04189

Report No.: CERN-TH-2020-170; DESY-20-173; arXiv:2010.09744

Abstract: We provide an easy method to obtain the kinetic energy fraction in gravitational waves, generated during a cosmological first-order phase transition, as a function of only the wall velocity and quantities that can be determined from the particle physics model at the nucleation temperature. This generalizes recent work that achieved this goal for detonations. Here we present the corresponding results for deflagrations and hybrids. Unlike for detonations, the sound speed in the symmetric phase also enters the analysis. We perform a detailed comparison between our model-independent approach and other approaches in the literature. We provide a Python code snippet to determine the kinetic energy fraction $K$ as a function of the wall velocity, the two speeds of sound and the strength parameter of the phase transition. We also assess how realistic sizable deviations in speed of sound are close to the phase transition temperature in a specific model.

Keyword(s): velocity: acoustic ; energy: kinetic ; critical phenomena: temperature ; gravitational radiation ; nucleation ; hybrid ; LISA