Emergent area laws from entangled matrices

Alexander Frenkel; Sean A. Hartnoll

doi:10.1007/JHEP05(2023)084

Emergent area laws from entangled matrices

Alexander Frenkel
, Sean A. Hartnoll

Simons Center for Geometry & Physics

University of Cambridge

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

We consider a wavefunction of large N matrices supported close to an emergent classical fuzzy sphere geometry. The SU(N) Gauss law of the theory enforces correlations between the matrix degrees of freedom associated to a geometric subregion and their complement. We call this ‘Gauss law entanglement’. We show that the subregion degrees of freedom transform under a single dominant, low rank representation of SU(N). The corresponding Gauss law entanglement entropy is given by the logarithm of the dimension of this dominant representation. It is found that, after coarse-graining in momentum space, the SU(N) Gauss law entanglement entropy is proportional to the geometric area bounding the subregion. The constant of proportionality goes like the inverse of an emergent Maxwell coupling constant, reminiscent of gravitational entropy.

Original language	English
Article number	84
Journal	Journal of High Energy Physics
Volume	2023
Issue number	5
DOIs	https://doi.org/10.1007/JHEP05(2023)084
State	Published - May 2023

Keywords

1/N Expansion
M(atrix) Theories
Non-Commutative Geometry

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10.1007/JHEP05(2023)084

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title = "Emergent area laws from entangled matrices",

abstract = "We consider a wavefunction of large N matrices supported close to an emergent classical fuzzy sphere geometry. The SU(N) Gauss law of the theory enforces correlations between the matrix degrees of freedom associated to a geometric subregion and their complement. We call this {\textquoteleft}Gauss law entanglement{\textquoteright}. We show that the subregion degrees of freedom transform under a single dominant, low rank representation of SU(N). The corresponding Gauss law entanglement entropy is given by the logarithm of the dimension of this dominant representation. It is found that, after coarse-graining in momentum space, the SU(N) Gauss law entanglement entropy is proportional to the geometric area bounding the subregion. The constant of proportionality goes like the inverse of an emergent Maxwell coupling constant, reminiscent of gravitational entropy.",

keywords = "1/N Expansion, M(atrix) Theories, Non-Commutative Geometry",

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year = "2023",

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doi = "10.1007/JHEP05(2023)084",

language = "English",

volume = "2023",

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AU - Frenkel, Alexander

AU - Hartnoll, Sean A.

PY - 2023/5

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N2 - We consider a wavefunction of large N matrices supported close to an emergent classical fuzzy sphere geometry. The SU(N) Gauss law of the theory enforces correlations between the matrix degrees of freedom associated to a geometric subregion and their complement. We call this ‘Gauss law entanglement’. We show that the subregion degrees of freedom transform under a single dominant, low rank representation of SU(N). The corresponding Gauss law entanglement entropy is given by the logarithm of the dimension of this dominant representation. It is found that, after coarse-graining in momentum space, the SU(N) Gauss law entanglement entropy is proportional to the geometric area bounding the subregion. The constant of proportionality goes like the inverse of an emergent Maxwell coupling constant, reminiscent of gravitational entropy.

AB - We consider a wavefunction of large N matrices supported close to an emergent classical fuzzy sphere geometry. The SU(N) Gauss law of the theory enforces correlations between the matrix degrees of freedom associated to a geometric subregion and their complement. We call this ‘Gauss law entanglement’. We show that the subregion degrees of freedom transform under a single dominant, low rank representation of SU(N). The corresponding Gauss law entanglement entropy is given by the logarithm of the dimension of this dominant representation. It is found that, after coarse-graining in momentum space, the SU(N) Gauss law entanglement entropy is proportional to the geometric area bounding the subregion. The constant of proportionality goes like the inverse of an emergent Maxwell coupling constant, reminiscent of gravitational entropy.

KW - 1/N Expansion

KW - M(atrix) Theories

KW - Non-Commutative Geometry

UR - https://www.scopus.com/pages/publications/85159219760

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DO - 10.1007/JHEP05(2023)084

M3 - Article

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SN - 1126-6708

VL - 2023

JO - Journal of High Energy Physics

JF - Journal of High Energy Physics

IS - 5

M1 - 84

ER -

Emergent area laws from entangled matrices

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