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Auteur principal: Alishahiha, Mohsen
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2510.25700
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author Alishahiha, Mohsen
author_facet Alishahiha, Mohsen
contents Motivated by the pseudo-entropy program, we study timelike subregion complexity within the holographic Complexity-equal-Volume framework, extending previous spatial constructions to Lorentzian boundary intervals. For hyperbolic timelike regions in pure AdS, we compute the enclosed bulk volume and show that, despite the Lorentzian embedding, the resulting complexity is purely real. We generalize the analysis to AdS black brane geometries, where extremal surfaces may either remain entirely outside the horizon or penetrate it, placing their timelike branch inside the black brane interior. In both configurations, the complexity exhibits the same universal UV divergences as the spacelike case, yet it receives no imaginary contribution, highlighting its causal and geometric origin. This reality stands in sharp contrast to the complex-valued pseudo-entropy and indicates that holographic complexity retains a genuinely geometric, real character even under Lorentzian continuation.
format Preprint
id arxiv_https___arxiv_org_abs_2510_25700
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Timelike Holographic Complexity
Alishahiha, Mohsen
High Energy Physics - Theory
Motivated by the pseudo-entropy program, we study timelike subregion complexity within the holographic Complexity-equal-Volume framework, extending previous spatial constructions to Lorentzian boundary intervals. For hyperbolic timelike regions in pure AdS, we compute the enclosed bulk volume and show that, despite the Lorentzian embedding, the resulting complexity is purely real. We generalize the analysis to AdS black brane geometries, where extremal surfaces may either remain entirely outside the horizon or penetrate it, placing their timelike branch inside the black brane interior. In both configurations, the complexity exhibits the same universal UV divergences as the spacelike case, yet it receives no imaginary contribution, highlighting its causal and geometric origin. This reality stands in sharp contrast to the complex-valued pseudo-entropy and indicates that holographic complexity retains a genuinely geometric, real character even under Lorentzian continuation.
title Timelike Holographic Complexity
topic High Energy Physics - Theory
url https://arxiv.org/abs/2510.25700