Entanglement wedge reconstruction using the Petz map

Creators: Chen, Chi-Fang; Penington, Geoffrey; Salton, Grant

Abstract

At the heart of recent progress in AdS/CFT is the question of subregion duality, or entanglement wedge reconstruction: which part(s) of the boundary CFT are dual to a given subregion of the bulk? This question can be answered by appealing to the quantum error correcting properties of holography, and it was recently shown that robust bulk (entanglement wedge) reconstruction can be achieved using a universal recovery channel known as the twirled Petz map. In short, one can use the twirled Petz map to recover bulk data from a subset of the boundary. However, this map involves an averaging procedure over bulk and boundary modular time, and hence it can be somewhat intractable to evaluate in practice. We show that a much simpler channel, the Petz map, is sufficient for entanglement wedge reconstruction for any code space of fixed finite dimension — no twirling is required. Moreover, the error in the reconstruction will always be non-perturbatively small. From a quantum information perspective, we prove a general theorem extending the use of the Petz map as a general-purpose recovery channel to subsystem and operator algebra quantum error correction.

Additional Information

© 2020 The Author(s). This article is distributed under the terms of the Creative Commons Attribution License (CC-BY 4.0), which permits any use, distribution and reproduction in any medium, provided the original author(s) and source are credited. Article funded by SCOAP3. Received: November 5, 2019; Accepted: January 8, 2020; Published: January 28, 2020. We would like to thank Patrick Hayden, Richard Nally, and Michael Walter for valuable discussions. We would also like to thank Howard Barnum for insightful and stimulating conversation in the early stages of this project. CFC was supported by the Physics/Applied Physics/SLAC Summer Research Program for undergraduates at Stanford University. GP is supported by the Simons Foundation "It from Qubit" collaboration, AFOSR grant number FA9550-16-1-0082 and DOE award DE-SC0019. GS was supported by an IQIM postdoctoral fellowship at Caltech, DOE award Quantum Error Correction and Spacetime Geometry DE-SC0018407, the Simons Foundation "It from Qubit" collaboration, and by the Stanford Institute for Theoretical Physics.

Attached Files

Published - Chen2020_Article_EntanglementWedgeReconstructio.pdf

Submitted - 1902.02844v1.pdf

Files

1902.02844v1.pdf

Files (467.3 kB)

Name	Size	Download all
1902.02844v1.pdf md5:a9002f8e47cdd7526f6b77e81d46cbb6	175.5 kB	Preview Download
Chen2020_Article_EntanglementWedgeReconstructio.pdf md5:af620773ed198d42b76c9f2c9afb4252	291.8 kB	Preview Download

Additional details

	All versions	This version
Views	0	0
Downloads	0	0
Data volume	0 Bytes	0 Bytes