Litcius/Paper detail

Entanglement wedge reconstruction using the Petz map

Chi-Fang Chen, Geoffrey Penington, Grant Salton

2020Journal of High Energy Physics54 citationsDOIOpen Access PDF

Abstract

A bstract 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.

Topics & Concepts

Wedge (geometry)Quantum entanglementMathematicsDimension (graph theory)QuantumBoundary (topology)Quantum informationQuantum error correctionAlgorithmQuantum channelPure mathematicsModular designSpace (punctuation)Discrete mathematicsAmplitude damping channelOperator (biology)Topology (electrical circuits)Quantum computerDual (grammatical number)Extension (predicate logic)Hilbert spaceQuantum capacityMathematical analysisOperator algebraAlgebra over a fieldQuantum systemUnitary stateGeometryChannel (broadcasting)FactorizationBitwise operationPhysicsError detection and correctionQuantum many-body systemsQuantum Computing Algorithms and ArchitectureQuantum Information and Cryptography