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Holographic black hole formation and scrambling in time-ordered correlators

Holographic black hole formation and scrambling in time-ordered correlators
Holographic black hole formation and scrambling in time-ordered correlators
We describe a holographic mechanism for black hole formation via the collision of two shockwaves in three-dimensional anti-de Sitter spacetime. In the dual conformal field theory (CFT), a two-shockwave state corresponds to the insertion of two boosted precursor operators in complementary Rindler patches. Their operator product expansion is initially described by a universal mean field spectrum of exchanged states, which is dominated by operator dimensions that grow exponentially in the boost parameter. We propose their mean value as diagnosing the mass of the collision product in the bulk. It crosses the CFT heavy state threshold after two scrambling times, in accordance with expectations about black hole formation in general relativity. Our analysis also allows us to identify the scrambling characteristics usually associated with out-of-time-order correlation functions, using only the internal composition of thermal in-time-order correlators.
arXiv
Chowdhury, Pratyusha
a6bdfd8b-9013-4467-adfd-2c1cdebe6b95
Haehl, Felix M.
eb0d74fd-0d8b-4b1b-8686-79d43c2a3a5f
Sanchez Garrido, Adrian
6add42c4-992e-455c-a098-f26e85168537
Zhao, Ying
f7e965ce-4cc7-4489-8683-644d85b58137
Chowdhury, Pratyusha
a6bdfd8b-9013-4467-adfd-2c1cdebe6b95
Haehl, Felix M.
eb0d74fd-0d8b-4b1b-8686-79d43c2a3a5f
Sanchez Garrido, Adrian
6add42c4-992e-455c-a098-f26e85168537
Zhao, Ying
f7e965ce-4cc7-4489-8683-644d85b58137

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Abstract

We describe a holographic mechanism for black hole formation via the collision of two shockwaves in three-dimensional anti-de Sitter spacetime. In the dual conformal field theory (CFT), a two-shockwave state corresponds to the insertion of two boosted precursor operators in complementary Rindler patches. Their operator product expansion is initially described by a universal mean field spectrum of exchanged states, which is dominated by operator dimensions that grow exponentially in the boost parameter. We propose their mean value as diagnosing the mass of the collision product in the bulk. It crosses the CFT heavy state threshold after two scrambling times, in accordance with expectations about black hole formation in general relativity. Our analysis also allows us to identify the scrambling characteristics usually associated with out-of-time-order correlation functions, using only the internal composition of thermal in-time-order correlators.

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2511.03784v1 - Author's Original
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Published date: 5 November 2025
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Identifiers

Local EPrints ID: 507573
URI: http://eprints.soton.ac.uk/id/eprint/507573
DOI: doi:10.48550/arXiv.2511.03784
PURE UUID: 22117bdc-9380-40f5-89c9-336136a61d1b
ORCID for Felix M. Haehl: ORCID iD orcid.org/0000-0001-7426-0962
ORCID for Adrian Sanchez Garrido: ORCID iD orcid.org/0000-0003-2313-5859

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Date deposited: 12 Dec 2025 17:45
Last modified: 13 Dec 2025 03:06

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Author: Pratyusha Chowdhury
Author: Felix M. Haehl ORCID iD
Author: Adrian Sanchez Garrido ORCID iD
Author: Ying Zhao

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