The black hole information paradox: from Hawking radiation to holographic correspondence

The black hole information paradox: from Hawking radiation to holographic correspondence

In this thesis, we explore the correlation between the thermal entropy of the Hawking radiation and its entanglement entropy. We begin by presenting the particle creation phenomenon due to the spacetime curvature of a black hole using Hawking’s “semiclassical” approach. This calculation also suggest...

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Main Author: Kristanto, Aaron Valencio
Other Authors: Leek Meng Lee
Format: Final Year Project
Language:English
Published: Nanyang Technological University 2024
Subjects:
Physics
Hawking radiation
Black hole
Information paradox
AdS/CFT
Holographic correspondence
Online Access:https://hdl.handle.net/10356/175541
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1755412024-04-29T15:39:32Z The black hole information paradox: from Hawking radiation to holographic correspondence Kristanto, Aaron Valencio Leek Meng Lee School of Physical and Mathematical Sciences MLLeek@ntu.edu.sg Physics Hawking radiation Black hole Information paradox AdS/CFT Holographic correspondence In this thesis, we explore the correlation between the thermal entropy of the Hawking radiation and its entanglement entropy. We begin by presenting the particle creation phenomenon due to the spacetime curvature of a black hole using Hawking’s “semiclassical” approach. This calculation also suggests that black holes possess a thermal entropy proportional to its event horizon area, S ∼ R2, in (3+1) dimensions. This prompts us to find the correlation between a bulk volume and its boundary area, which can be described by the AdS/CFT correspondence. Using the Ryu-Takayanagi formula, at zero and finite temperature cases, the regulated geodesic length in AdS3 was then found to be directly proportional to the entanglement entropy of a finite CFT2 interval, whose endpoints coincide with that of the AdS3 geodesic. As an original contribution, this thesis shows that the finite-temperature entanglement entropy reduces to the zero-temperature entanglement entropy and thermal black hole entropy in the T → 0 and T → ∞ limits, respectively. Furthermore, the high-temperature entanglement entropy in (2+1)-dimensional black hole spacetime has the relation S ∼ R, analogous to the (3+1)-dimensional case. We thus postulate that the entanglement entropy is a generalisation of the thermal black hole entropy in any number of dimensions. The AdS/CFT correspondence is therefore an alternative way to compute the black hole entropy. Bachelor's degree 2024-04-29T03:29:41Z 2024-04-29T03:29:41Z 2024 Final Year Project (FYP) Kristanto, A. V. (2024). The black hole information paradox: from Hawking radiation to holographic correspondence. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/175541 https://hdl.handle.net/10356/175541 en application/pdf Nanyang Technological University
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Physics
Hawking radiation
Black hole
Information paradox
AdS/CFT
Holographic correspondence
spellingShingle Physics
Hawking radiation
Black hole
Information paradox
AdS/CFT
Holographic correspondence
Kristanto, Aaron Valencio
The black hole information paradox: from Hawking radiation to holographic correspondence
description In this thesis, we explore the correlation between the thermal entropy of the Hawking radiation and its entanglement entropy. We begin by presenting the particle creation phenomenon due to the spacetime curvature of a black hole using Hawking’s “semiclassical” approach. This calculation also suggests that black holes possess a thermal entropy proportional to its event horizon area, S ∼ R2, in (3+1) dimensions. This prompts us to find the correlation between a bulk volume and its boundary area, which can be described by the AdS/CFT correspondence. Using the Ryu-Takayanagi formula, at zero and finite temperature cases, the regulated geodesic length in AdS3 was then found to be directly proportional to the entanglement entropy of a finite CFT2 interval, whose endpoints coincide with that of the AdS3 geodesic. As an original contribution, this thesis shows that the finite-temperature entanglement entropy reduces to the zero-temperature entanglement entropy and thermal black hole entropy in the T → 0 and T → ∞ limits, respectively. Furthermore, the high-temperature entanglement entropy in (2+1)-dimensional black hole spacetime has the relation S ∼ R, analogous to the (3+1)-dimensional case. We thus postulate that the entanglement entropy is a generalisation of the thermal black hole entropy in any number of dimensions. The AdS/CFT correspondence is therefore an alternative way to compute the black hole entropy.
author2 Leek Meng Lee
author_facet Leek Meng Lee
Kristanto, Aaron Valencio
format Final Year Project
author Kristanto, Aaron Valencio
author_sort Kristanto, Aaron Valencio
title The black hole information paradox: from Hawking radiation to holographic correspondence
title_short The black hole information paradox: from Hawking radiation to holographic correspondence
title_full The black hole information paradox: from Hawking radiation to holographic correspondence
title_fullStr The black hole information paradox: from Hawking radiation to holographic correspondence
title_full_unstemmed The black hole information paradox: from Hawking radiation to holographic correspondence
title_sort black hole information paradox: from hawking radiation to holographic correspondence
publisher Nanyang Technological University
publishDate 2024
url https://hdl.handle.net/10356/175541
_version_ 1806059897790398464

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