Litcius/Paper detail

The Pair-instability Mass Gap for Black Holes

S. E. Woosley, Alexander Heger

2021The Astrophysical Journal Letters184 citationsDOIOpen Access PDF

Abstract

Abstract Stellar evolution theory predicts a “gap” in the black hole birth function caused by the pair instability. Many presupernova stars that have a core mass below some limiting value, M low , after all pulsational activity is finished, collapse to black holes, while more massive ones, up to some limiting value, M high , explode, promptly and completely, as pair-instability supernovae. Previous work has suggested M low ≈ 50 M ⊙ and M high ≈ 130 M ⊙ . These calculations have been challenged by recent LIGO observations that show many black holes merging with individual masses M low ≳ 65 M ⊙ . Here we explore four factors affecting the theoretical estimates for the boundaries of this mass gap: nuclear reaction rates, evolution in detached binaries, rotation, and hyper-Eddington accretion after black hole birth. Current uncertainties in reaction rates by themselves allow M low to rise to 64 M ⊙ and M high as large as 161 M ⊙ . Rapid rotation could further increase M low to ∼70 M ⊙ , depending on the treatment of magnetic torques. Evolution in detached binaries and super-Eddington accretion can, with great uncertainty, increase M low still further. Dimensionless Kerr parameters close to unity are allowed for the more massive black holes produced in close binaries, though they are generally smaller.

Topics & Concepts

PhysicsAstrophysicsBlack hole (networking)Accretion (finance)Binary black holeStellar black holeDimensionless quantityIntermediate-mass black holeLIGOLimitingSupermassive black holeSpin-flipAccretion discStarsStellar evolutionGamma-ray burst progenitorsWork (physics)Rotation (mathematics)AstronomyCritical mass (sociodynamics)FuzzballSchwarzschild radiusRotating black holeInstabilityNeutron starAstrophysical Phenomena and ObservationsPulsars and Gravitational Waves ResearchGamma-ray bursts and supernovae