Background independent tensor networks

Akers, Chris; Wei, Annie Y.

doi:10.21468/SciPostPhys.17.3.090

SciPost Physics

Background independent tensor networks

Chris Akers, Annie Y. Wei

SciPost Phys. 17, 090 (2024) · published 25 September 2024

doi: 10.21468/SciPostPhys.17.3.090
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Abstract

Conventional holographic tensor networks can be described as toy holographic maps constructed from many small linear maps acting in a spatially local way, all connected together with "background entanglement", i.e. links of a fixed state, often the maximally entangled state. However, these constructions fall short of modeling real holographic maps. One reason is that their "areas" are trivial, taking the same value for all states, unlike in gravity where the geometry is dynamical. Recently, new constructions have ameliorated this issue by adding degrees of freedom that "live on the links". This makes areas non-trivial, equal to the background entanglement piece plus a new positive piece that depends on the state of the link degrees of freedom. Nevertheless, this still has the downside that there is background entanglement, and hence it only models relatively limited code subspaces in which every area has a definite minimum value. In this note, we simply point out that a version of these constructions goes one step further: they can be background independent, with no background entanglement in the holographic map. This is advantageous because it allows tensor networks to model holographic maps for larger code subspaces. In addition to pointing this out, we address some subtleties involved in making it work.

TY  - JOUR
PB  - SciPost Foundation
DO  - 10.21468/SciPostPhys.17.3.090
TI  - Background independent tensor networks
PY  - 2024/09/25
UR  - https://scipost.org/SciPostPhys.17.3.090
JF  - SciPost Physics
JA  - SciPost Phys.
VL  - 17
IS  - 3
SP  - 090
A1  - Akers, Chris
AU  - Wei, Annie Y.
AB  - Conventional holographic tensor networks can be described as toy holographic maps constructed from many small linear maps acting in a spatially local way, all connected together with "background entanglement", i.e. links of a fixed state, often the maximally entangled state. However, these constructions fall short of modeling real holographic maps. One reason is that their "areas" are trivial, taking the same value for all states, unlike in gravity where the geometry is dynamical. Recently, new constructions have ameliorated this issue by adding degrees of freedom that "live on the links". This makes areas non-trivial, equal to the background entanglement piece plus a new positive piece that depends on the state of the link degrees of freedom. Nevertheless, this still has the downside that there is background entanglement, and hence it only models relatively limited code subspaces in which every area has a definite minimum value. In this note, we simply point out that a version of these constructions goes one step further: they can be background independent, with no background entanglement in the holographic map. This is advantageous because it allows tensor networks to model holographic maps for larger code subspaces. In addition to pointing this out, we address some subtleties involved in making it work.
ER  -

@Article{10.21468/SciPostPhys.17.3.090,
	title={{Background independent tensor networks}},
	author={Chris Akers and Annie Y. Wei},
	journal={SciPost Phys.},
	volume={17},
	pages={090},
	year={2024},
	publisher={SciPost},
	doi={10.21468/SciPostPhys.17.3.090},
	url={https://scipost.org/10.21468/SciPostPhys.17.3.090},
}

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¹ Chris Akers,
² Annie Y. Wei

Funders for the research work leading to this publication