Litcius/Paper detail

μ-distortion around stupendously large primordial black holes

Heling Deng

2021Journal of Cosmology and Astroparticle Physics16 citationsDOI

Abstract

Abstract In a variety of mechanisms generating primordial black holes, each black hole is expected to form along with a surrounding underdense region that roughly compensates the black hole mass. This region will propagate outwards and expand as a shell at the speed of sound in the homogeneous background. Dissipation of the shell due to Silk damping could lead to detectable μ-distortion in the CMB spectrum: if black holes are rare on the last scattering surface, the signal(s) would be pointlike; whereas if there are a sufficient number of them, we could have a uniform distortion in the CMB sky. While the current bound on the average μ-distortion is |μ̅| ≲ 10 -4 , the standard ΛCDM model predicts |μ̅| ∼ 10 -8 , which could possibly be detected in future missions. It is shown in this work that the non-observation of μ̅ beyond ΛCDM can place a new upper bound on the density of supermassive primordial black holes within the mass range 10 6 M ☉ ≲ M ≲ 10 15 M ☉ . Furthermore, black holes with initial mass M ≳ 10 12 M ☉ could leave a pointlike distortion with μ ≳10 -8 at an angular scale ∼ 1° in CMB, and its non-observation would impose an even more stringent bound on the population of these stupendously large primordial black holes.

Topics & Concepts

PhysicsSupermassive black holeAstrophysicsCosmic microwave backgroundBlack hole (networking)Distortion (music)Binary black holeIntermediate-mass black holePrimordial black holeBar (unit)LambdaParticle physicsGalaxyQuantum mechanicsGravitational waveComputer networkRouting protocolMeteorologyRouting (electronic design automation)AnisotropyComputer scienceOptoelectronicsCMOSLink-state routing protocolAmplifierBlack Holes and Theoretical PhysicsCosmology and Gravitation TheoriesPulsars and Gravitational Waves Research