Universality of black hole thermodynamics beyond the thermal approximation

Christian Corda; Carlo Cafaro

doi:10.1142/S021827182544016X

Universality of black hole thermodynamics beyond the thermal approximation

Christian Corda
, Carlo Cafaro

Nanoscale Science and Engineering

University at Albany

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Mathur and Mehta were awarded the third prize in the 2023 Gravity Research Foundation Essay Competition for their work demonstrating the universality of black hole (BH) thermodynamics. Their research established that any Extremely Compact Object (ECO) exhibits the same thermodynamic properties as a BH, irrespective of the presence of an event horizon. This significant finding was derived under the assumption that the BH emission spectrum behaves thermally. However, compelling arguments rooted in energy conservation and the BH back reaction indicate that the spectrum of Hawking radiation cannot be perfectly thermal. In this paper, we explore the extension of Mathur and Mehta’s findings to scenarios where the radiation spectrum deviates from exact thermal behavior, utilizing the concept of the BH dynamical state.

Original language	English
Article number	2544016
Journal	International Journal of Modern Physics D
Volume	34
Issue number	16
DOIs	https://doi.org/10.1142/S021827182544016X
State	Published - Dec 1 2025

Keywords

Physics of black holes
black hole evaporation
black hole thermodynamics
quantum aspects of black holes

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10.1142/S021827182544016X

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abstract = "Mathur and Mehta were awarded the third prize in the 2023 Gravity Research Foundation Essay Competition for their work demonstrating the universality of black hole (BH) thermodynamics. Their research established that any Extremely Compact Object (ECO) exhibits the same thermodynamic properties as a BH, irrespective of the presence of an event horizon. This significant finding was derived under the assumption that the BH emission spectrum behaves thermally. However, compelling arguments rooted in energy conservation and the BH back reaction indicate that the spectrum of Hawking radiation cannot be perfectly thermal. In this paper, we explore the extension of Mathur and Mehta{\textquoteright}s findings to scenarios where the radiation spectrum deviates from exact thermal behavior, utilizing the concept of the BH dynamical state.",

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AB - Mathur and Mehta were awarded the third prize in the 2023 Gravity Research Foundation Essay Competition for their work demonstrating the universality of black hole (BH) thermodynamics. Their research established that any Extremely Compact Object (ECO) exhibits the same thermodynamic properties as a BH, irrespective of the presence of an event horizon. This significant finding was derived under the assumption that the BH emission spectrum behaves thermally. However, compelling arguments rooted in energy conservation and the BH back reaction indicate that the spectrum of Hawking radiation cannot be perfectly thermal. In this paper, we explore the extension of Mathur and Mehta’s findings to scenarios where the radiation spectrum deviates from exact thermal behavior, utilizing the concept of the BH dynamical state.

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KW - black hole evaporation

KW - black hole thermodynamics

KW - quantum aspects of black holes

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JO - International Journal of Modern Physics D

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Universality of black hole thermodynamics beyond the thermal approximation

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