Bounds on operator dimensions in 2D conformal field theories

A bstract We extend the work of Hellerman [1] to derive an upper bound on the conformal dimension Δ 2 of the next-to-lowest nontrival primary operator in unitary, modular-invariant two-dimensional conformal field theories without chiral primary operators, with total central charge c tot > 2. The...

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Bibliographic Details
Published in:The journal of high energy physics 2014-05, Vol.2014 (5), p.1-16, Article 91
Main Authors: Qualls, Joshua D., Shapere, Alfred D.
Format: Article
Language:English
Subjects:
Asymptotic properties
Boundaries
Classical and Quantum Gravitation
Elementary Particles
Field theory
Gravitation theory
High energy physics
Lower bounds
Operators
Physics
Physics and Astronomy
Quantum Field Theories
Quantum Field Theory
Quantum Physics
Relativity Theory
String Theory
Two dimensional
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Summary:A bstract We extend the work of Hellerman [1] to derive an upper bound on the conformal dimension Δ 2 of the next-to-lowest nontrival primary operator in unitary, modular-invariant two-dimensional conformal field theories without chiral primary operators, with total central charge c tot > 2. The bound we find is of the same form as found by Hellerman for ∆ 1 : ∆ 2 ≤ + O (1). We obtain a similar bound on the conformal dimension Δ 3 , and present a method for deriving bounds on Δ n for any n , under slightly modified assumptions. For asymptotically large c tot and n ≲ exp( πc /12), we show that ∆ n ≤ + O (1). This implies an asymptotic lower bound of order exp( πc tot / 12) on the number of primary operators of dimension ≤ c tot / 12 + O (1), in the large- c limit. In dual gravitational theories, this corresponds to a lower bound in the flat-space limit on the number of gravitational states without boundary excitations, of mass less than or equal to 1 / 4 G N .
ISSN:1029-8479
1029-8479
DOI:10.1007/JHEP05(2014)091