4.4 Article

Leading order corrections to the quantum extremal surface prescription

期刊

JOURNAL OF HIGH ENERGY PHYSICS
卷 -, 期 4, 页码 -

出版社

SPRINGER
DOI: 10.1007/JHEP04(2021)062

关键词

AdS-CFT Correspondence; Nonperturbative Effects; Gauge-gravity correspondence

资金

  1. US Department of Energy [DE-SC0018944, DE-SC0019127]
  2. Simons foundation
  3. AFOSR [FA9550-16-1-0082]
  4. DOE [DE-SC0019380]
  5. U.S. Department of Energy (DOE) [DE-SC0018944] Funding Source: U.S. Department of Energy (DOE)

向作者/读者索取更多资源

The study shows that a naive application of the quantum extremal surface (QES) prescription can lead to paradoxes and requires corrections at leading order. Corrections occur when there is a second QES with larger generalized entropy than the minimal QES at leading order, and a large amount of highly incompressible bulk entropy between the surfaces. The source of these corrections is traced back to a failure in the assumptions used in the derivation of the QES prescription using the replica trick, and a more careful derivation correctly computes the corrections.
We show that a naive application of the quantum extremal surface (QES) prescription can lead to paradoxical results and must be corrected at leading order. The corrections arise when there is a second QES (with strictly larger generalized entropy at leading order than the minimal QES), together with a large amount of highly incompressible bulk entropy between the two surfaces. We trace the source of the corrections to a failure of the assumptions used in the replica trick derivation of the QES prescription, and show that a more careful derivation correctly computes the corrections. Using tools from one-shot quantum Shannon theory (smooth min- and max-entropies), we generalize these results to a set of refined conditions that determine whether the QES prescription holds. We find similar refinements to the conditions needed for entanglement wedge reconstruction (EWR), and show how EWR can be reinterpreted as the task of one-shot quantum state merging (using zero-bits rather than classical bits), a task gravity is able to achieve optimally efficiently.

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