Collapse of a rotating supermassive star to a supermassive black hole: Fully relattvistic simulations

Masaru Shibata; Stuart L. Shapiro

doi:10.1086/341516

Collapse of a rotating supermassive star to a supermassive black hole: Fully relattvistic simulations

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Abstract

We follow the collapse in axisymmetry of a uniformly rotating, supermassive star (SMS) to a supermassive black hole in full general relativity. The initial SMS of arbitrary mass M is marginally unstable to radial collapse and rotates at the mass-shedding limit. The collapse proceeds homologously early on and results in the appearance of an apparent horizon at the center. Although our integration terminates before final equilibrium is achieved, we determine that the final black hole will contain about 90% of the total mass of the system and will have a spin parameter JIM² ∼ 0.75. The remaining gas forms a rotating disk about the nascent hole.

Original language	English (US)
Pages (from-to)	L39-L43
Journal	Astrophysical Journal
Volume	572
Issue number	1 II
DOIs	https://doi.org/10.1086/341516
State	Published - Jun 10 2002

Keywords

Black hole physics
Hydrodynamics
Relativity
Stars: rotation

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

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10.1086/341516

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abstract = "We follow the collapse in axisymmetry of a uniformly rotating, supermassive star (SMS) to a supermassive black hole in full general relativity. The initial SMS of arbitrary mass M is marginally unstable to radial collapse and rotates at the mass-shedding limit. The collapse proceeds homologously early on and results in the appearance of an apparent horizon at the center. Although our integration terminates before final equilibrium is achieved, we determine that the final black hole will contain about 90% of the total mass of the system and will have a spin parameter JIM2 ∼ 0.75. The remaining gas forms a rotating disk about the nascent hole.",

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N2 - We follow the collapse in axisymmetry of a uniformly rotating, supermassive star (SMS) to a supermassive black hole in full general relativity. The initial SMS of arbitrary mass M is marginally unstable to radial collapse and rotates at the mass-shedding limit. The collapse proceeds homologously early on and results in the appearance of an apparent horizon at the center. Although our integration terminates before final equilibrium is achieved, we determine that the final black hole will contain about 90% of the total mass of the system and will have a spin parameter JIM2 ∼ 0.75. The remaining gas forms a rotating disk about the nascent hole.

AB - We follow the collapse in axisymmetry of a uniformly rotating, supermassive star (SMS) to a supermassive black hole in full general relativity. The initial SMS of arbitrary mass M is marginally unstable to radial collapse and rotates at the mass-shedding limit. The collapse proceeds homologously early on and results in the appearance of an apparent horizon at the center. Although our integration terminates before final equilibrium is achieved, we determine that the final black hole will contain about 90% of the total mass of the system and will have a spin parameter JIM2 ∼ 0.75. The remaining gas forms a rotating disk about the nascent hole.

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Collapse of a rotating supermassive star to a supermassive black hole: Fully relattvistic simulations

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