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Gravitational waves from a holographic phase transition

Fëanor Reuben Ares, Mark Hindmarsh, Carlos Hoyos, Niko Jokela

2021Journal of High Energy Physics29 citationsDOIOpen Access PDF

Abstract

Abstract We investigate first order phase transitions in a holographic setting of five-dimensional Einstein gravity coupled to a scalar field, constructing phase diagrams of the dual field theory at finite temperature. We scan over the two-dimensional parameter space of a simple bottom-up model and map out important quantities for the phase transition: the region where first order phase transitions take place; the latent heat, the transition strength parameter α , and the stiffness. We find that α is generically in the range 0 . 1 to 0 . 3, and is strongly correlated with the stiffness (the square of the sound speed in a barotropic fluid). Using the LISA Cosmology Working Group gravitational wave power spectrum model corrected for kinetic energy suppression at large α and non-conformal stiffness, we outline the observational prospects at the future space-based detectors LISA and TianQin. A TeV-scale hidden sector with a phase transition described by the model could be observable at both detectors.

Topics & Concepts

PhysicsGravitational waveObservablePhase transitionScalar fieldDark energyScalar (mathematics)GravitationCosmologyHolographic principleClassical mechanicsCritical phenomenaPhase (matter)Quantum mechanicsQuantum electrodynamicsInflation (cosmology)UniverseField (mathematics)Gravitational-wave observatoryGravitational fieldGravitational energyTheoretical physicsHolographyQuantum phase transitionSpectral densityEinsteinScalar field theoryBarotropic fluidNon-GaussianityCosmic microwave backgroundAmplitudeParameter spacePhase diagramStatistical physicsCritical point (mathematics)SpacetimePhase spaceCosmology and Gravitation TheoriesBlack Holes and Theoretical PhysicsPulsars and Gravitational Waves Research