A General Proof of the Quantum Null Energy Condition

We prove a conjectured lower bound on \(\left< T_{--}(x) \right>_\psi\) in any state \(\psi\) of a relativistic QFT dubbed the Quantum Null Energy Condition (QNEC). The bound is given by the second order shape deformation, in the null direction, of the geometric entanglement entropy of an enta...

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Bibliographic Details
Published inarXiv.org
Main Authors Balakrishnan, Srivatsan, Faulkner, Thomas, Khandker, Zuhair U, Wang, Huajia
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 27.03.2019
Subjects
Causality
Deformation mechanisms
Entanglement
Hamiltonian functions
Inclusions
Lower bounds
Nesting
Operators (mathematics)
Physics - General Relativity and Quantum Cosmology
Physics - High Energy Physics - Theory
Physics - Quantum Physics
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Summary:We prove a conjectured lower bound on \(\left< T_{--}(x) \right>_\psi\) in any state \(\psi\) of a relativistic QFT dubbed the Quantum Null Energy Condition (QNEC). The bound is given by the second order shape deformation, in the null direction, of the geometric entanglement entropy of an entangling cut passing through \(x\). Our proof involves a combination of the two independent methods that were used recently to prove the weaker Averaged Null Energy Condition (ANEC). In particular the properties of modular Hamiltonians under shape deformations for the state \(\psi\) play an important role, as do causality considerations. We study the two point function of a "probe" operator \(\mathcal{O}\) in the state \(\psi\) and use a lightcone limit to evaluate this correlator. Instead of causality in time we consider \emph{causality in modular time} for the modular evolved probe operators, which we constrain using Tomita-Takesaki theory as well as certain generalizations pertaining to the theory of modular inclusions. The QNEC follows from very similar considerations to the derivation of the chaos bound and the causality sum rule. We use a kind of defect Operator Product Expansion to apply the replica trick to these modular flow computations, and the displacement operator plays an important role. Our approach was inspired by the AdS/CFT proof of the QNEC which follows from properties of the Ryu-Takayanagi (RT) surface near the boundary of AdS, combined with the requirement of entanglement wedge nesting. Our methods were, as such, designed as a precise probe of the RT surface close to the boundary of a putative gravitational/stringy dual of \emph{any} QFT with an interacting UV fixed point. We also prove a higher spin version of the QNEC.
ISSN:2331-8422
DOI:10.48550/arxiv.1706.09432