Gravitational radiation from first-order phase transitions in the presence of a fluid

Giblin, John T.; Mertens, James B.

doi:10.1103/physrevd.90.023532

Cited by 107 publications

(87 citation statements)

References 79 publications

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“…The total spectrum is given in Eq. (19) by the sum of the signal generated by sound waves and by MHD turbulence. Since we set = 0.05 the signal from sound waves is dominant (c.f.…”

Section: Examples Of Gravitational Wave Spectramentioning

confidence: 99%

Science with the space-based interferometer eLISA. II: gravitational waves from cosmological phase transitions

Caprini

Hindmarsh

Huber

et al. 2016

J. Cosmol. Astropart. Phys.

858

1,311

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We investigate the potential for the eLISA space-based interferometer to detect the stochastic gravitational wave background produced by strong first-order cosmological phase transitions. We discuss the resulting contributions from bubble collisions, magnetohydrodynamic turbulence, and sound waves to the stochastic background, and estimate the total corresponding signal predicted in gravitational waves. The projected sensitivity of eLISA to cosmological phase transitions is computed in a model-independent way for various detector designs and configurations. By applying these results to several specific models, we demonstrate that eLISA is able to probe many wellmotivated scenarios beyond the Standard Model of particle physics predicting strong first-order cosmological phase transitions in the early Universe.

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“…The total spectrum is given in Eq. (19) by the sum of the signal generated by sound waves and by MHD turbulence. Since we set = 0.05 the signal from sound waves is dominant (c.f.…”

Section: Examples Of Gravitational Wave Spectramentioning

confidence: 99%

Science with the space-based interferometer eLISA. II: gravitational waves from cosmological phase transitions

Caprini

Hindmarsh

Huber

et al. 2016

J. Cosmol. Astropart. Phys.

858

1,311

View full text Add to dashboard Cite

show abstract

“…The production of GWs from a first-order phase transition originates from three sources: the collisions of bubbles walls [1][2][3][4][5]36,37], sound waves in the plasma formed after collision [57][58][59][60] and magnetohydrodynamics turbu-lences in the plasma [61][62][63][64][65]. As these three contributions should approximately linearly combine [12], the total energy density can be written…”

Section: Gravitational Wave Productionmentioning

confidence: 99%

Gravitational waves from a supercooled electroweak phase transition and their detection with pulsar timing arrays

et al. 2017

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We investigate the properties of a stochastic gravitational wave background produced by a first-order electroweak phase transition in the regime of extreme supercooling. We study a scenario whereby the percolation temperature that signifies the completion of the transition, T p , is as low as a few MeV (nucleosynthesis temperature), while most of the true vacuum bubbles are formed much earlier at the nucleation temperature, T n ∼ 50 GeV. This implies that the gravitational wave spectrum is mainly produced by the collisions of large bubbles and characterised by a large amplitude and a peak frequency as low as f ∼ 10 −9 −10 −7 Hz. We show that such a scenario can occur in (but not limited to) a model based on a non-linear realisation of the electroweak gauge group, so that the Higgs vacuum configuration is altered by a cubic coupling. In order to carefully quantify the evolution of the phase transition of this model over such a wide temperature range we go beyond the usual fast transition approximation, taking into account the expansion of the Universe as well as the behaviour of the nucleation probability at low temperatures. Our computation shows that there exists a range of parameters for which the gravitational wave spectrum lies at the edge between the exclusion limits of current pulsar timing array experiments and the detection band of the future Square Kilometre Array observatory.

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“…where h is the dimensionless Hubble parameter, Ω ϕ stands for the scalar field contribution from collisions of bubble walls [61][62][63][64][65][66], Ω sw for the contribution from sound waves in plasma after the bubble collisions [67][68][69][70], and Ω turb for the contribution from magnetohydrodynamic (MHD) turbulence in plasma [71][72][73][74]. Following [12], each contribution is given for a given set of the parameters (T t , α,β) with the velocity of bubble wall v w and the κ ϕ , κ v , and κ turb which are the fraction of vacuum energy, respectively, converted into gradient energy of scalar field, bulk motion of the fluid, and MHD turbulence.…”

Section: Signal From the Hidden Sector Qcdmentioning

confidence: 99%

Gravitational waves from hidden QCD phase transition

2017

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Drastic changes in the early Universe such as first-order phase transition can produce a stochastic gravitational wave (GW) background. We investigate the testability of a scale invariant extension of the standard model (SM) using the GW background produced by the chiral phase transition in a strongly interacting QCD-like hidden sector, which, via a SM singlet real scalar mediator, triggers the electroweak phase transition. Using the Nambu-Jona-Lasinio method in a mean field approximation we estimate the GW signal and find that it can be tested by future space-based detectors.

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Gravitational radiation from first-order phase transitions in the presence of a fluid

Cited by 107 publications

References 79 publications

Science with the space-based interferometer eLISA. II: gravitational waves from cosmological phase transitions

Science with the space-based interferometer eLISA. II: gravitational waves from cosmological phase transitions

Gravitational waves from a supercooled electroweak phase transition and their detection with pulsar timing arrays

Gravitational waves from hidden QCD phase transition

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