A universal inequality on the unitary 2D CFT partition function

A universal inequality on the unitary 2D CFT partition function

Abstract We prove the conjecture proposed by Hartman, Keller and Stoica (HKS) [1]: the grand-canonical free energy of a unitary 2D CFT with a sparse spectrum below the scaling dimension c 12 $$ \frac{c}{12} $$ + ϵ and below the twist c 12 $$ \frac{c}{12} $$ is universal in the large c limit for all...

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Bibliographic Details
Main Authors: Indranil Dey, Sridip Pal, Jiaxin Qiao
Format: Article
Language:English
Published: SpringerOpen 2025-07-01
Series:Journal of High Energy Physics
Subjects:
Conformal and W Symmetry
Field Theories in Lower Dimensions
AdS-CFT Correspondence
Black Holes
Online Access:https://doi.org/10.1007/JHEP07(2025)163
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Summary:Abstract We prove the conjecture proposed by Hartman, Keller and Stoica (HKS) [1]: the grand-canonical free energy of a unitary 2D CFT with a sparse spectrum below the scaling dimension c 12 $$ \frac{c}{12} $$ + ϵ and below the twist c 12 $$ \frac{c}{12} $$ is universal in the large c limit for all β L β R ≠ 4π 2. The technique of the proof allows us to derive a one-parameter (with parameter α ∈ (0, 1]) family of universal inequalities on the unitary 2D CFT partition function with general central charge c ⩾ 0, using analytical modular bootstrap. We derive an iterative equation for the domain of validity of the inequality on the (β L , β R ) plane. The infinite iteration of this equation gives the boundary of maximal-validity domain, which depends on the parameter α in the inequality. In the c → ∞ limit, with the additional assumption of a sparse spectrum below the scaling dimension c 12 $$ \frac{c}{12} $$ + ϵ and the twist αc 12 $$ \frac{\alpha c}{12} $$ (with α ∈ (0, 1] fixed), our inequality shows that the grand-canonical free energy exhibits a universal large c behavior in the maximal-validity domain. This domain, however, does not cover the entire (β L , β R ) plane, except in the case of α = 1. For α = 1, this proves the conjecture proposed by HKS [1], and for α < 1, it quantifies how sparseness in twist affects the regime of universality. Furthermore, this implies a precise lower bound on the temperature of near-extremal BTZ black holes, above which we can trust the black hole thermodynamics.
ISSN:1029-8479

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