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Main Author: Mishra, Aryaman
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.10784
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author Mishra, Aryaman
author_facet Mishra, Aryaman
contents The correlation function in Ads/CFT are correlation of the operator insertions on the boundary (at CFT) through the complete geometry of bulk. These are represented by Witten diagrams which at tree level doesn't have any quantum corrections. Generally, correlation functions are of low scaling (or conformal) dimension, $Δ$, which is related to the mass of insertion of the scalar operator by, $Δ(Δ- 1) = m^2 L_{AdS}^2$. At low scaling dimensions the operator insertion on the CFT boundary does not back-react the metric of the geometry. On the other hand, at large scaling dimensions which scale with central charge the operator is considered heavy. This leads to an interesting question of what in the dual bulk (AdS) geometry of such heavy operators. At the heavy limit $Δ= m L_{AdS}$, which means that the mass of the operator insertion is large too. The two-point function of heavy-operator is assumed to be Black hole in $(d+1)$-dimensions and the two-point form of CFT is recovered by calculating the action. In $3$-dimension we have more control over the geometry because of existence of exact metric called Bañados metric with boundary stress-tensor insertion along with a map which maps it to Euclidean Poincare upper half plane. These methods are used to find the geometry for three-point function. The geometry is not simply of a black-hole but a wormhole solution for whose action is calculated which recovers the "square" of the classical DOZZ formula. We review the recent work of arXiv:2306.15105 and arXiv:2307.13188 in this thesis to form an understanding of heavy operators in the context of AdS/CFT.
format Preprint
id arxiv_https___arxiv_org_abs_2405_10784
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Dynamics of Heavy Operators in $AdS/CFT$
Mishra, Aryaman
High Energy Physics - Theory
The correlation function in Ads/CFT are correlation of the operator insertions on the boundary (at CFT) through the complete geometry of bulk. These are represented by Witten diagrams which at tree level doesn't have any quantum corrections. Generally, correlation functions are of low scaling (or conformal) dimension, $Δ$, which is related to the mass of insertion of the scalar operator by, $Δ(Δ- 1) = m^2 L_{AdS}^2$. At low scaling dimensions the operator insertion on the CFT boundary does not back-react the metric of the geometry. On the other hand, at large scaling dimensions which scale with central charge the operator is considered heavy. This leads to an interesting question of what in the dual bulk (AdS) geometry of such heavy operators. At the heavy limit $Δ= m L_{AdS}$, which means that the mass of the operator insertion is large too. The two-point function of heavy-operator is assumed to be Black hole in $(d+1)$-dimensions and the two-point form of CFT is recovered by calculating the action. In $3$-dimension we have more control over the geometry because of existence of exact metric called Bañados metric with boundary stress-tensor insertion along with a map which maps it to Euclidean Poincare upper half plane. These methods are used to find the geometry for three-point function. The geometry is not simply of a black-hole but a wormhole solution for whose action is calculated which recovers the "square" of the classical DOZZ formula. We review the recent work of arXiv:2306.15105 and arXiv:2307.13188 in this thesis to form an understanding of heavy operators in the context of AdS/CFT.
title Dynamics of Heavy Operators in $AdS/CFT$
topic High Energy Physics - Theory
url https://arxiv.org/abs/2405.10784