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Entanglement Content of Quantum Particle Excitations III. Graph Partition Functions

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Entanglement Content of Quantum Particle Excitations III. Graph Partition Functions. / Castro-Alvaredo, Olalla A.; De Fazio, Cecilia; Doyon, Benjamin; Szecsenyi, Istvan.

In: JOURNAL OF MATHEMATICAL PHYSICS, Vol. 60, No. 8, 082301, 01.08.2019.

Research output: Contribution to journalArticle

Harvard

Castro-Alvaredo, OA, De Fazio, C, Doyon, B & Szecsenyi, I 2019, 'Entanglement Content of Quantum Particle Excitations III. Graph Partition Functions', JOURNAL OF MATHEMATICAL PHYSICS, vol. 60, no. 8, 082301. https://doi.org/10.1063/1.5098892

APA

Castro-Alvaredo, O. A., De Fazio, C., Doyon, B., & Szecsenyi, I. (2019). Entanglement Content of Quantum Particle Excitations III. Graph Partition Functions. JOURNAL OF MATHEMATICAL PHYSICS, 60(8), [082301]. https://doi.org/10.1063/1.5098892

Vancouver

Castro-Alvaredo OA, De Fazio C, Doyon B, Szecsenyi I. Entanglement Content of Quantum Particle Excitations III. Graph Partition Functions. JOURNAL OF MATHEMATICAL PHYSICS. 2019 Aug 1;60(8). 082301. https://doi.org/10.1063/1.5098892

Author

Castro-Alvaredo, Olalla A. ; De Fazio, Cecilia ; Doyon, Benjamin ; Szecsenyi, Istvan. / Entanglement Content of Quantum Particle Excitations III. Graph Partition Functions. In: JOURNAL OF MATHEMATICAL PHYSICS. 2019 ; Vol. 60, No. 8.

Bibtex Download

@article{eaf904dd107c439fa16780e59bb61638,
title = "Entanglement Content of Quantum Particle Excitations III. Graph Partition Functions",
abstract = "We consider two measures of entanglement, the logarithmic negativity, and the entanglement entropy, between regions of space in excited states of many-body systems formed by a finite number of particle excitations. In Papers I and II [O. A. Castro-Alvaredo et al., J. High Energy Phys. 2018(10), 39; ibid., e-print arXiv:1904.01035 (2019)], it has been shown in one-dimensional free-particle models that, in the limit of large system’s and regions’ sizes, the contribution from the particles is given by the entanglement of natural qubit states, representing the uniform distribution of particles in space. We show that the replica logarithmic negativity and R{\'e}nyi entanglement entropy of such qubit states are equal to the partition functions of certain graphs, formed out of Wick pairings, which encode the topology of the manifold induced by permutation twist fields. Using this new connection, we provide a general proof, in the massive free boson model, which the qubit result holds in any dimensionality and for any regions’ shapes and topology. The proof is based on clustering and the permutation-twist exchange relations and is potentially generalizable to other situations, such as lattice models, particle and hole excitations above generalized Gibbs ensembles, and interacting integrable models.",
author = "Castro-Alvaredo, {Olalla A.} and {De Fazio}, Cecilia and Benjamin Doyon and Istvan Szecsenyi",
year = "2019",
month = "8",
day = "1",
doi = "10.1063/1.5098892",
language = "English",
volume = "60",
journal = "JOURNAL OF MATHEMATICAL PHYSICS",
issn = "0022-2488",
publisher = "American Institute of Physics",
number = "8",

}

RIS (suitable for import to EndNote) Download

TY - JOUR

T1 - Entanglement Content of Quantum Particle Excitations III. Graph Partition Functions

AU - Castro-Alvaredo, Olalla A.

AU - De Fazio, Cecilia

AU - Doyon, Benjamin

AU - Szecsenyi, Istvan

PY - 2019/8/1

Y1 - 2019/8/1

N2 - We consider two measures of entanglement, the logarithmic negativity, and the entanglement entropy, between regions of space in excited states of many-body systems formed by a finite number of particle excitations. In Papers I and II [O. A. Castro-Alvaredo et al., J. High Energy Phys. 2018(10), 39; ibid., e-print arXiv:1904.01035 (2019)], it has been shown in one-dimensional free-particle models that, in the limit of large system’s and regions’ sizes, the contribution from the particles is given by the entanglement of natural qubit states, representing the uniform distribution of particles in space. We show that the replica logarithmic negativity and Rényi entanglement entropy of such qubit states are equal to the partition functions of certain graphs, formed out of Wick pairings, which encode the topology of the manifold induced by permutation twist fields. Using this new connection, we provide a general proof, in the massive free boson model, which the qubit result holds in any dimensionality and for any regions’ shapes and topology. The proof is based on clustering and the permutation-twist exchange relations and is potentially generalizable to other situations, such as lattice models, particle and hole excitations above generalized Gibbs ensembles, and interacting integrable models.

AB - We consider two measures of entanglement, the logarithmic negativity, and the entanglement entropy, between regions of space in excited states of many-body systems formed by a finite number of particle excitations. In Papers I and II [O. A. Castro-Alvaredo et al., J. High Energy Phys. 2018(10), 39; ibid., e-print arXiv:1904.01035 (2019)], it has been shown in one-dimensional free-particle models that, in the limit of large system’s and regions’ sizes, the contribution from the particles is given by the entanglement of natural qubit states, representing the uniform distribution of particles in space. We show that the replica logarithmic negativity and Rényi entanglement entropy of such qubit states are equal to the partition functions of certain graphs, formed out of Wick pairings, which encode the topology of the manifold induced by permutation twist fields. Using this new connection, we provide a general proof, in the massive free boson model, which the qubit result holds in any dimensionality and for any regions’ shapes and topology. The proof is based on clustering and the permutation-twist exchange relations and is potentially generalizable to other situations, such as lattice models, particle and hole excitations above generalized Gibbs ensembles, and interacting integrable models.

UR - http://www.scopus.com/inward/record.url?scp=85075212079&partnerID=8YFLogxK

U2 - 10.1063/1.5098892

DO - 10.1063/1.5098892

M3 - Article

VL - 60

JO - JOURNAL OF MATHEMATICAL PHYSICS

JF - JOURNAL OF MATHEMATICAL PHYSICS

SN - 0022-2488

IS - 8

M1 - 082301

ER -

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