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Main Authors: Chen, Bin, Liu, Yuefeng, Yu, Boyang
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2404.11423
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author Chen, Bin
Liu, Yuefeng
Yu, Boyang
author_facet Chen, Bin
Liu, Yuefeng
Yu, Boyang
contents In this study, we explore the correlation functions of thin-shell operators, represented semiclassically by a homogeneous, thin interface of dust particles. Employing the monodromy method, we successfully compute the contribution from the Virasoro vacuum block and present the monodromy equation in a closed form without assuming the probe limit. Although an analytical solution to the monodromy equation remains difficult, we demonstrate that it is perturbatively solvable within specific limits, including the probe, the heavy-shell, and the early-time limits. Moreover, we compare our results with gravitational calculations and find precise agreement. We strengthen our findings by proving that the thermal correlation functions in gravity, after an inverse Laplace transformation, satisfy the field theory's monodromy equation. Additionally, we identify an infinite series of unphysical solutions to the monodromy equation and discuss their potential geometrical duals.
format Preprint
id arxiv_https___arxiv_org_abs_2404_11423
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Correlation Function Of Thin-Shell Operators
Chen, Bin
Liu, Yuefeng
Yu, Boyang
High Energy Physics - Theory
In this study, we explore the correlation functions of thin-shell operators, represented semiclassically by a homogeneous, thin interface of dust particles. Employing the monodromy method, we successfully compute the contribution from the Virasoro vacuum block and present the monodromy equation in a closed form without assuming the probe limit. Although an analytical solution to the monodromy equation remains difficult, we demonstrate that it is perturbatively solvable within specific limits, including the probe, the heavy-shell, and the early-time limits. Moreover, we compare our results with gravitational calculations and find precise agreement. We strengthen our findings by proving that the thermal correlation functions in gravity, after an inverse Laplace transformation, satisfy the field theory's monodromy equation. Additionally, we identify an infinite series of unphysical solutions to the monodromy equation and discuss their potential geometrical duals.
title Correlation Function Of Thin-Shell Operators
topic High Energy Physics - Theory
url https://arxiv.org/abs/2404.11423