English

Relational bulk reconstruction from modular flow

High Energy Physics - Theory 2024-08-16 v2 Quantum Physics

Abstract

The entanglement wedge reconstruction paradigm in AdS/CFT states that for a bulk qudit within the entanglement wedge of a boundary subregion Aˉ\bar{A}, operators acting on the bulk qudit can be reconstructed as CFT operators on Aˉ\bar{A}. This naturally fits within the framework of quantum error correction, with the CFT states containing the bulk qudit forming a code protected against the erasure of the boundary subregion AA. In this paper, we set up and study a framework for relational bulk reconstruction in holography: given two code subspaces both protected against erasure of the boundary region AA, the goal is to relate the operator reconstructions between the two spaces. To accomplish this, we assume that the two code subspaces are smoothly connected by a one-parameter family of codes all protected against the erasure of AA, and that the maximally-entangled states on these codes are all full-rank. We argue that such code subspaces can naturally be constructed in holography in a "measurement-based" setting. In this setting, we derive a flow equation for the operator reconstruction of a fixed code subspace operator using modular theory which can, in principle, be integrated to relate the reconstructed operators all along the flow. We observe a striking resemblance between our formulas for relational bulk reconstruction and the infinite-time limit of Connes cocycle flow, and take some steps towards making this connection more rigorous. We also provide alternative derivations of our reconstruction formulas in terms of a canonical reconstruction map we call the modular reflection operator.

Keywords

Cite

@article{arxiv.2403.02377,
  title  = {Relational bulk reconstruction from modular flow},
  author = {Onkar Parrikar and Harshit Rajgadia and Vivek Singh and Jonathan Sorce},
  journal= {arXiv preprint arXiv:2403.02377},
  year   = {2024}
}

Comments

25 pages + appendices; v2 has minor clarifications and is published in JHEP

R2 v1 2026-06-28T15:08:53.508Z