Horizon-bound objects: Kerr-Vaidya solutions

Pravin K. Dahal; Swayamsiddha Maharana; Fil Simovic; Daniel R. Terno

doi:10.1007/s10714-024-03345-2

Horizon-bound objects: Kerr-Vaidya solutions

Pravin K. Dahal, Swayamsiddha Maharana, Fil Simovic, Daniel R. Terno

School of Mathematical and Physical Sciences

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Abstract

Kerr-Vaidya metrics are the simplest dynamical axially-symmetric solutions, all of which violate the null energy condition and thus are consistent with the formation of a trapped region in finite time according to distant observers. We examine different classes of Kerr-Vaidya metrics, and find two which possess spherically-symmetric counterparts that are compatible with the finite formation time of a trapped region. These solutions describe evaporating black holes and expanding white holes. We demonstrate a consistent description of accreting black holes based on the ingoing Kerr-Vaidya metric with increasing mass, and show that the model can be extended to cases where the angular momentum to mass ratio varies. For such metrics we describe conditions on their dynamical evolution required to maintain asymptotic flatness.Pathologies are also identified in the evaporating white hole geometry in the form of an intermediate singularity accessible by timelike observers. We also describe a generalization of the equivalence between Rindler and Schwarzschild horizons to Kerr-Vaidya black holes, and describe the relevant geometric constructions.

Original language	English
Article number	20
Pages (from-to)	1-38
Number of pages	38
Journal	General Relativity and Gravitation
Volume	57
Issue number	1
DOIs	https://doi.org/10.1007/s10714-024-03345-2
Publication status	Published - Jan 2025

Bibliographical note

Keywords

Astrophysical black holes
Evaporating black holes
Kerr-Vaidya metrics
Semi-classical gravity
White holes

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10.1007/s10714-024-03345-2Licence: CC BY

Publisher version (open access)Final published version, 611 KBLicence: CC BY

Cite this

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abstract = "Kerr-Vaidya metrics are the simplest dynamical axially-symmetric solutions, all of which violate the null energy condition and thus are consistent with the formation of a trapped region in finite time according to distant observers. We examine different classes of Kerr-Vaidya metrics, and find two which possess spherically-symmetric counterparts that are compatible with the finite formation time of a trapped region. These solutions describe evaporating black holes and expanding white holes. We demonstrate a consistent description of accreting black holes based on the ingoing Kerr-Vaidya metric with increasing mass, and show that the model can be extended to cases where the angular momentum to mass ratio varies. For such metrics we describe conditions on their dynamical evolution required to maintain asymptotic flatness.Pathologies are also identified in the evaporating white hole geometry in the form of an intermediate singularity accessible by timelike observers. We also describe a generalization of the equivalence between Rindler and Schwarzschild horizons to Kerr-Vaidya black holes, and describe the relevant geometric constructions.",

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AU - Simovic, Fil

AU - Terno, Daniel R.

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N2 - Kerr-Vaidya metrics are the simplest dynamical axially-symmetric solutions, all of which violate the null energy condition and thus are consistent with the formation of a trapped region in finite time according to distant observers. We examine different classes of Kerr-Vaidya metrics, and find two which possess spherically-symmetric counterparts that are compatible with the finite formation time of a trapped region. These solutions describe evaporating black holes and expanding white holes. We demonstrate a consistent description of accreting black holes based on the ingoing Kerr-Vaidya metric with increasing mass, and show that the model can be extended to cases where the angular momentum to mass ratio varies. For such metrics we describe conditions on their dynamical evolution required to maintain asymptotic flatness.Pathologies are also identified in the evaporating white hole geometry in the form of an intermediate singularity accessible by timelike observers. We also describe a generalization of the equivalence between Rindler and Schwarzschild horizons to Kerr-Vaidya black holes, and describe the relevant geometric constructions.

AB - Kerr-Vaidya metrics are the simplest dynamical axially-symmetric solutions, all of which violate the null energy condition and thus are consistent with the formation of a trapped region in finite time according to distant observers. We examine different classes of Kerr-Vaidya metrics, and find two which possess spherically-symmetric counterparts that are compatible with the finite formation time of a trapped region. These solutions describe evaporating black holes and expanding white holes. We demonstrate a consistent description of accreting black holes based on the ingoing Kerr-Vaidya metric with increasing mass, and show that the model can be extended to cases where the angular momentum to mass ratio varies. For such metrics we describe conditions on their dynamical evolution required to maintain asymptotic flatness.Pathologies are also identified in the evaporating white hole geometry in the form of an intermediate singularity accessible by timelike observers. We also describe a generalization of the equivalence between Rindler and Schwarzschild horizons to Kerr-Vaidya black holes, and describe the relevant geometric constructions.

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KW - Semi-classical gravity

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Horizon-bound objects: Kerr-Vaidya solutions

Abstract

Bibliographical note

Keywords

Access to Document

Other files and links

Do black holes exist?

Cite this

Horizon-bound objects: Kerr-Vaidya solutions

Abstract

Bibliographical note

Keywords

Access to Document

Other files and links

Projects

Do black holes exist?

Cite this