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Dark radiation isocurvature from cosmological phase transitions

Matthew R. Buckley, Peizhi Du, Nicolas Fernandez, Mitchell J. Weikert

2024Journal of Cosmology and Astroparticle Physics12 citationsDOIOpen Access PDF

Abstract

Abstract Cosmological first order phase transitions are typically associated with physics beyond the Standard Model, and thus of great theoretical and observational interest. Models of phase transitions where the energy is mostly converted to dark radiation can be constrained through limits on the dark radiation energy density (parameterized by Δ N eff ). However, the current constraint (Δ N eff < 0.3) assumes the perturbations are adiabatic. We point out that a broad class of non-thermal first order phase transitions that start during inflation but do not complete until after reheating leave a distinct imprint in the scalar field from bubble nucleation. Dark radiation inherits the perturbation from the scalar field when the phase transition completes, leading to large-scale isocurvature that would be observable in the CMB. We perform a detailed calculation of the isocurvature power spectrum and derive constraints on Δ N eff based on CMB+BAO data. For a reheating temperature of T rh and a nucleation temperature T * , the constraint is approximately Δ N eff ≲ 10 -5 ( T * / T rh ) -4 , which can be much stronger than the adiabatic result. We also point out that since perturbations of dark radiation have a non-Gaussian origin, searches for non-Gaussianity in the CMB could place a stringent bound on Δ N eff as well.

Topics & Concepts

PhysicsDark energyCosmologyAstrophysicsDark matterBackground radiationLambda-CDM modelCosmological perturbation theoryPhase transitionDark radiationCosmological constantPhase (matter)RadiationParticle physicsAstronomyTheoretical physicsNuclear physicsQuantum mechanicsCosmology and Gravitation TheoriesGalaxies: Formation, Evolution, PhenomenaDark Matter and Cosmic Phenomena