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Main Authors: Akers, Chris, Soni, Ronak M., Wei, Annie Y.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2404.03651
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author Akers, Chris
Soni, Ronak M.
Wei, Annie Y.
author_facet Akers, Chris
Soni, Ronak M.
Wei, Annie Y.
contents Holographic tensor networks model AdS/CFT, but so far they have been limited by involving only systems that are very different from gravity. Unfortunately, we cannot straightforwardly discretize gravity to incorporate it, because that would break diffeomorphism invariance. In this note, we explore a resolution. In low dimensions gravity can be written as a topological gauge theory, which can be discretized without breaking gauge-invariance. However, new problems arise. Foremost, we now need a qualitatively new kind of "area operator," which has no relation to the number of links along the cut and is instead topological. Secondly, the inclusion of matter becomes trickier. We successfully construct a tensor network both including matter and with this new type of area. Notably, while this area is still related to the entanglement in "edge mode" degrees of freedom, the edge modes are no longer bipartite entangled pairs. Instead they are highly multipartite. Along the way, we calculate the entropy of novel subalgebras in a particular topological gauge theory. We also show that the multipartite nature of the edge modes gives rise to non-commuting area operators, a property that other tensor networks do not exhibit.
format Preprint
id arxiv_https___arxiv_org_abs_2404_03651
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Multipartite edge modes and tensor networks
Akers, Chris
Soni, Ronak M.
Wei, Annie Y.
High Energy Physics - Theory
Strongly Correlated Electrons
Quantum Physics
Holographic tensor networks model AdS/CFT, but so far they have been limited by involving only systems that are very different from gravity. Unfortunately, we cannot straightforwardly discretize gravity to incorporate it, because that would break diffeomorphism invariance. In this note, we explore a resolution. In low dimensions gravity can be written as a topological gauge theory, which can be discretized without breaking gauge-invariance. However, new problems arise. Foremost, we now need a qualitatively new kind of "area operator," which has no relation to the number of links along the cut and is instead topological. Secondly, the inclusion of matter becomes trickier. We successfully construct a tensor network both including matter and with this new type of area. Notably, while this area is still related to the entanglement in "edge mode" degrees of freedom, the edge modes are no longer bipartite entangled pairs. Instead they are highly multipartite. Along the way, we calculate the entropy of novel subalgebras in a particular topological gauge theory. We also show that the multipartite nature of the edge modes gives rise to non-commuting area operators, a property that other tensor networks do not exhibit.
title Multipartite edge modes and tensor networks
topic High Energy Physics - Theory
Strongly Correlated Electrons
Quantum Physics
url https://arxiv.org/abs/2404.03651