The thermodynamics of a black hole in equilibrium implies the breakdown of Einstein equations on a macroscopic near-horizon shell
We study a black hole of mass M, enclosed within a spherical box, in equilibrium with its Hawking radiation. We show that the spacetime geometry inside the box is described by the Oppenheimer-Volkoff equations for radiation, except for a {\em thin shell} around the horizon. We use the maximum entrop...
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| Διαθέσιμο Online: | https://doi.org/10.1007/JHEP01(2016)144 http://hdl.handle.net/10889/11479 |
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nemertes-10889-114792022-09-05T04:59:21Z The thermodynamics of a black hole in equilibrium implies the breakdown of Einstein equations on a macroscopic near-horizon shell Anastopoulos, Charis Savvidou, Ntina Αναστασόπουλος, Χάρης Σαββίδου, Ντίνα General relativity Quantum cosmology SCOAP3 Γενική θεωρία της σχετικότητας Κβαντική κοσμολογία We study a black hole of mass M, enclosed within a spherical box, in equilibrium with its Hawking radiation. We show that the spacetime geometry inside the box is described by the Oppenheimer-Volkoff equations for radiation, except for a {\em thin shell} around the horizon. We use the maximum entropy principle to show that the invariant width of the shell is of order M−−√, its entropy is of order M and its temperature of order 1/M−−√ (in Planck units). Thus, the width of the shell is {\em much larger} than the Planck length. Our approach is to insist on thermodynamic consistency when classical general relativity coexists with the Hawking temperature in the description of a gravitating system. No assumptions about an underlying theory are made and no restrictions are placed on the origins of the new physics near the horizon. We only employ classical general relativity and the principles of thermodynamics. Our result is strengthened by an analysis of the trace anomaly associated to the geometry inside the box, i.e., the regime where quantum field effects become significant corresponds to the shells of maximum entropy around the horizon. 2018-08-01T06:16:57Z 2018-08-01T06:16:57Z 2016-01 Journal (paper) Anastopoulos, C. & Savvidou, N. "The thermodynamics of a black hole in equilibrium implies the breakdown of Einstein equations on a macroscopic near-horizon shell". Journal of high energy physics (2016): 144. https://doi.org/10.1007/JHEP01(2016)144 https://doi.org/10.1007/JHEP01(2016)144 http://hdl.handle.net/10889/11479 en application/pdf Journal of high energy physics |
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Nemertes |
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English |
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General relativity Quantum cosmology SCOAP3 Γενική θεωρία της σχετικότητας Κβαντική κοσμολογία |
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General relativity Quantum cosmology SCOAP3 Γενική θεωρία της σχετικότητας Κβαντική κοσμολογία Anastopoulos, Charis Savvidou, Ntina The thermodynamics of a black hole in equilibrium implies the breakdown of Einstein equations on a macroscopic near-horizon shell |
| description |
We study a black hole of mass M, enclosed within a spherical box, in equilibrium with its Hawking radiation. We show that the spacetime geometry inside the box is described by the Oppenheimer-Volkoff equations for radiation, except for a {\em thin shell} around the horizon. We use the maximum entropy principle to show that the invariant width of the shell is of order M−−√, its entropy is of order M and its temperature of order 1/M−−√ (in Planck units). Thus, the width of the shell is {\em much larger} than the Planck length. Our approach is to insist on thermodynamic consistency when classical general relativity coexists with the Hawking temperature in the description of a gravitating system. No assumptions about an underlying theory are made and no restrictions are placed on the origins of the new physics near the horizon. We only employ classical general relativity and the principles of thermodynamics. Our result is strengthened by an analysis of the trace anomaly associated to the geometry inside the box, i.e., the regime where quantum field effects become significant corresponds to the shells of maximum entropy around the horizon. |
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Αναστασόπουλος, Χάρης |
| author_facet |
Αναστασόπουλος, Χάρης Anastopoulos, Charis Savvidou, Ntina |
| format |
Journal (paper) |
| author |
Anastopoulos, Charis Savvidou, Ntina |
| author_sort |
Anastopoulos, Charis |
| title |
The thermodynamics of a black hole in equilibrium implies the breakdown of Einstein equations on a macroscopic near-horizon shell |
| title_short |
The thermodynamics of a black hole in equilibrium implies the breakdown of Einstein equations on a macroscopic near-horizon shell |
| title_full |
The thermodynamics of a black hole in equilibrium implies the breakdown of Einstein equations on a macroscopic near-horizon shell |
| title_fullStr |
The thermodynamics of a black hole in equilibrium implies the breakdown of Einstein equations on a macroscopic near-horizon shell |
| title_full_unstemmed |
The thermodynamics of a black hole in equilibrium implies the breakdown of Einstein equations on a macroscopic near-horizon shell |
| title_sort |
thermodynamics of a black hole in equilibrium implies the breakdown of einstein equations on a macroscopic near-horizon shell |
| publishDate |
2018 |
| url |
https://doi.org/10.1007/JHEP01(2016)144 http://hdl.handle.net/10889/11479 |
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