The refined quantum extremal surface prescription from the asymptotic equipartition property

TL;DR

This paper refines the quantum extremal surface prescription by integrating one-shot quantum information theory, specifically the asymptotic equipartition property, to better understand entanglement entropy and phase transitions in holography and black hole physics.

Contribution

It introduces a novel AEP replica trick to derive a refined QES prescription, connecting quantum information concepts with quantum gravity, and demonstrates its implications for black hole entropy calculations.

Findings

Refined QES prescription derived using AEP replica trick.

Corrections to QES do not occur for pure bulk states in higher Rénnyi entropies.

Large corrections to the Page curve in a superposed black hole radiation model.

Abstract

Information-theoretic ideas have provided numerous insights in the progress of fundamental physics, especially in our pursuit of quantum gravity. In particular, the holographic entanglement entropy is a very useful tool in studying AdS/CFT, and its efficacy is manifested in the recent black hole page curve calculation. On the other hand, the one-shot information-theoretic entropies, such as the smooth min/max-entropies, are less discussed in AdS/CFT. They are however more fundamental entropy measures from the quantum information perspective and should also play pivotal roles in holography. We combine the technical methods from both quantum information and quantum gravity to put this idea on firm grounds. In particular, we study the quantum extremal surface (QES) prescription that was recently revised to highlight the significance of one-shot entropies in characterizing the QES phase transition. Motivated by the asymptotic equipartition property (AEP), we derive the refined quantum extremal surface prescription for fixed-area states via a novel AEP replica trick, demonstrating the synergy between quantum information and quantum gravity. We further prove that, when restricted to pure bulk marginal states, such corrections do not occur for the higher R\'enyi entropies of a boundary subregion in fixed-area states, meaning they always have sharp QES transitions. Our path integral derivation suggests that the refinement applies beyond AdS/CFT, and we confirm it in a black hole toy model by showing that the Page curve, for a black hole in a superposition of two radiation stages, receives a large correction that is consistent with the refined QES prescription.