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Autori principali: Choun, Yoon-Seok, Kim, Ki-Seok, Sin, Sang-Jin
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2312.16561
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author Choun, Yoon-Seok
Kim, Ki-Seok
Sin, Sang-Jin
author_facet Choun, Yoon-Seok
Kim, Ki-Seok
Sin, Sang-Jin
contents We propose a method to constrain the scaling dimension of the operators of the strongly interacting systems (SIS) using the holographic setup. %where the (d+1)-dimensional black hole is used to describe the d-dimensional SIS. We demonstrate our method using the holographic superconductor theory. The idea is to consider the inside as well as the outside of the AdS black hole in which the gap equations has higher order singularities. Then the equivalence principle requests the solution be smoothly connected at the horizon, which request the vanishing of log divergent term as well as an indefinite conditionally convergent terms that can lead to any real number according to Riemann. As a result, one gets quantized values of the scaling dimension of the condensing operator. This is a pleasant surprise because so far one gets the constraints on the scaling dimension only by a hard analysis with bootstrap ansatz.
format Preprint
id arxiv_https___arxiv_org_abs_2312_16561
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Quantum Scaling Dimension from the Equivalence principle
Choun, Yoon-Seok
Kim, Ki-Seok
Sin, Sang-Jin
High Energy Physics - Theory
We propose a method to constrain the scaling dimension of the operators of the strongly interacting systems (SIS) using the holographic setup. %where the (d+1)-dimensional black hole is used to describe the d-dimensional SIS. We demonstrate our method using the holographic superconductor theory. The idea is to consider the inside as well as the outside of the AdS black hole in which the gap equations has higher order singularities. Then the equivalence principle requests the solution be smoothly connected at the horizon, which request the vanishing of log divergent term as well as an indefinite conditionally convergent terms that can lead to any real number according to Riemann. As a result, one gets quantized values of the scaling dimension of the condensing operator. This is a pleasant surprise because so far one gets the constraints on the scaling dimension only by a hard analysis with bootstrap ansatz.
title Quantum Scaling Dimension from the Equivalence principle
topic High Energy Physics - Theory
url https://arxiv.org/abs/2312.16561