Abstract

Tensor networks provide a natural framework for exploring holographic duality because they obey entanglement area laws. They have been used to construct explicit toy models realizing many of the interesting structural features of the AdS/CFT correspondence, including the non-uniqueness of bulk operator reconstruction in the boundary theory. In this article, we explore the holographic properties of networks of random tensors. We find that our models naturally incorporate many features that are analogous to those of the AdS/CFT correspondence. When the bond dimension of the tensors is large, we show that the entanglement entropy of all boundary regions, whether connected or not, obey the Ryu-Takayanagi entropy formula, a fact closely related to known properties of the multipartite entanglement of assistance. We also discuss the behavior of Rényi entropies in our models and contrast it with AdS/CFT. Moreover, we find that each boundary region faithfully encodes the physics of the entire bulk entanglement wedge, i.e., the bulk region enclosed by the boundary region and the minimal surface. Our method is to interpret the average over random tensors as the partition function of a classical ferromagnetic Ising model, so that the minimal surfaces of Ryu-Takayanagi appear as domain walls. Upon including the analog of a bulk field, we find that our model reproduces the expected corrections to the Ryu-Takayanagi formula: the bulk minimal surface is displaced and the entropy is augmented by the entanglement of the bulk field. Increasing the entanglement of the bulk field ultimately changes the minimal surface behavior topologically, in a way similar to the effect of creating a black hole. Extrapolating bulk correlation functions to the boundary permits the calculation of the scaling dimensions of boundary operators, which exhibit a large gap between a small number of low-dimension operators and the rest. While we are primarily motivated by the AdS/CFT duality, the main results of the article define a more general form of bulk-boundary correspondence which could be useful for extending holography to other spacetimes.

Highlights

  • When the bond dimension of the tensors is large, we show that the entanglement entropy of all boundary regions, whether connected or not, obey the Ryu-Takayanagi entropy formula, a fact closely related to known properties of the multipartite entanglement of assistance

  • Upon including the analog of a bulk field, we find that our model reproduces the expected corrections to the Ryu-Takayanagi formula: the bulk minimal surface is displaced and the entropy is augmented by the entanglement of the bulk field

  • Tensor networks have been proposed [1] as a helpful tool for understanding holographic duality [2,3,4] due to the intuition that the entropy of a tensor network is bounded by an area law that agrees with the Ryu-Takayanagi (RT) formula [5]

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Summary

Introduction

Tensor networks have been proposed [1] as a helpful tool for understanding holographic duality [2,3,4] due to the intuition that the entropy of a tensor network is bounded by an area law that agrees with the Ryu-Takayanagi (RT) formula [5]. Using the random tensor network as a holographic mapping rather than a state on the boundary, we derive a formula for the entropy of a boundary region in the presence of an entangled state in the bulk. By calculating the entanglement entropy between a bulk region and the boundary in a given tensor network, we can verify that the random tensor network defines a bidirectional holographic code (BHC).

Definition of random tensor networks
Calculation of the second Renyi entropy
Ryu-Takayanagi formula
Ryu-Takayanagi formula for a bulk direct-product state
Ryu-Takayanagi formula with bulk state correction
Phase transition of the effective bulk geometry induced by bulk entanglement
Random tensor networks as bidirectional holographic codes
Code subspace
Entanglement wedges and error correction properties
Gauge invariance and absence of local operators
Higher Renyi entropies
Boundary two-point correlation functions
Fluctuations and corrections for finite bond dimension
The general bound on fluctuations
Improvement of the bound under a physical assumption
Possible effects of even smaller bond dimension
Relation to random measurements and the entanglement of assistance
Random tensor networks from 2-designs
10 Conclusion and discussion
A Analytic study of the three phases for a random bulk state
B Derivation of the error correction condition
C Uniqueness of minimal energy configuration for higher Renyi models
D Calculation of C2n in section 6
E Partition function of Ising model on the square lattice
F Average second Renyi entropy for 2-designs
G Contractions of stabilizer states

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