Litcius/Paper detail

Primordial black holes as dark matter and gravitational waves from single-field polynomial inflation

Guillermo Ballesteros, Julián Rey, Marco Taoso, Alfredo Urbano

2020Journal of Cosmology and Astroparticle Physics107 citationsDOIOpen Access PDF

Abstract

We consider the possibility that the majority of dark matter in our Universe consists of black holes of primordial origin. We determine the conditions under which such black holes may have originated from a single-field model of inflation characterized by a quartic polynomial potential. We also explore the effect of higher-dimensional operators. The large power spectrum of curvature perturbations that is needed for a large black hole abundance sources sizable second order tensor perturbations. The resulting stochastic background of primordial gravitational waves could be detected by the future space-based observatories LISA and DECIGO or --as long as we give up on the dark matter connection--by the ground-based Advanced LIGO-Virgo detector network.

Topics & Concepts

PhysicsPrimordial black holeDark matterInflation (cosmology)AstrophysicsGravitational waveUniverseBlack hole (networking)Dark energyHot dark matterDark fluidScalar field dark matterMicro black holeCosmic microwave backgroundGravitational wave backgroundHawking radiationRedshiftQuartic functionBinary black holeCurvatureCold dark matterWeak gravitational lensingCosmological perturbation theorySpectral densityAstronomyGravitationTensor (intrinsic definition)Baryon acoustic oscillationsPlanckParticle physicsOrder (exchange)Primordial fluctuationsCosmologyNon-GaussianityMatter power spectrumBig Bang (financial markets)Theoretical physicsPhysical cosmologyCosmology and Gravitation TheoriesDark Matter and Cosmic PhenomenaPulsars and Gravitational Waves Research