The effect of sound speed on the gravitational wave spectrum of first order phase transitions in the early universe
Abstract
Gravitational waves from first-order phase transitions are a promising probe of physics beyond the Standard Model, as many extensions of the standard model result in first-order phase transitions in the early universe, from which the resulting gravitational waves could be detectable with the upcoming Laser Interferometer Space Antenna (LISA). The properties of the phase transition and the resulting gravitational wave spectrum are determined by five key parameters: the nucleation temperature Tn, phase transition strength at the nucleation temperature αn, bubble wall speed vwall, transition rate β and the sound speed cs. Of these, the sound speed cs is determined by the equation of state p(T,φ). In most studies, the plasma of the early universe has been assumed to be ultrarelativistic and therefore following the bag equation of state with cs = 13. In this thesis, the PTtools simulation framework for first-order phase transitions, based on the Sound Shell Model, has been extended to include support for arbitrary equations of state and therefore for a temperature- and phase-dependent sound speed cs(T,φ). The thesis also functions as a reference manual for PTtools. The framework has been tested with the constant sound speed model, in which the sound speed is a different constant in each phase. The sound speed has been shown to have a significant effect on the resulting gravitational wave spectrum, especially when changing the sound speed results in a change in the type of the solution. This has laid the groundwork for simulating cosmological phase transitions with realistic equations of state. This will result in in gravitational wave spectra that can be used in the LISA data analysis pipeline to search for the existence and parameters of a first-order phase transition in the early universe.
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