Entanglement in quantum field theory via wavelet representations

Daniel J. George; Yuval R. Sanders; Mohsen Bagherimehrab; Barry C. Sanders; Gavin K. Brennen

doi:10.1103/PhysRevD.106.036025

Entanglement in quantum field theory via wavelet representations

Daniel J. George^*, Yuval R. Sanders, Mohsen Bagherimehrab, Barry C. Sanders, Gavin K. Brennen

^*Corresponding author for this work

ARC Centre of Excellence for Engineered Quantum Systems (EQuS)

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

9 Citations (Scopus)

Abstract

Quantum field theory (QFT) describes nature using continuous fields, but physical properties of QFT are usually revealed in terms of measurements of observables at a finite resolution. We describe a multiscale representation of free scalar bosonic and Ising model fermionic QFTs using wavelets. Making use of the orthogonality and self-similarity of the wavelet basis functions, we demonstrate some well-known relations such as scale-dependent subsystem entanglement entropy and renormalization of correlations in the ground state. We also find some new applications of the wavelet transform as a compressed representation of ground states of QFTs which can be used to illustrate quantum phase transitions via fidelity overlap and holographic entanglement of purification.

Original language	English
Article number	036025
Pages (from-to)	036025-1-036025-19
Number of pages	19
Journal	Physical Review D: covering particles, fields, gravitation, and cosmology
Volume	106
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevD.106.036025
Publication status	Published - 26 Aug 2022

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10.1103/PhysRevD.106.036025

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title = "Entanglement in quantum field theory via wavelet representations",

abstract = "Quantum field theory (QFT) describes nature using continuous fields, but physical properties of QFT are usually revealed in terms of measurements of observables at a finite resolution. We describe a multiscale representation of free scalar bosonic and Ising model fermionic QFTs using wavelets. Making use of the orthogonality and self-similarity of the wavelet basis functions, we demonstrate some well-known relations such as scale-dependent subsystem entanglement entropy and renormalization of correlations in the ground state. We also find some new applications of the wavelet transform as a compressed representation of ground states of QFTs which can be used to illustrate quantum phase transitions via fidelity overlap and holographic entanglement of purification. ",

author = "George, {Daniel J.} and Sanders, {Yuval R.} and Mohsen Bagherimehrab and Sanders, {Barry C.} and Brennen, {Gavin K.}",

year = "2022",

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doi = "10.1103/PhysRevD.106.036025",

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AU - George, Daniel J.

AU - Sanders, Yuval R.

AU - Bagherimehrab, Mohsen

AU - Sanders, Barry C.

AU - Brennen, Gavin K.

PY - 2022/8/26

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N2 - Quantum field theory (QFT) describes nature using continuous fields, but physical properties of QFT are usually revealed in terms of measurements of observables at a finite resolution. We describe a multiscale representation of free scalar bosonic and Ising model fermionic QFTs using wavelets. Making use of the orthogonality and self-similarity of the wavelet basis functions, we demonstrate some well-known relations such as scale-dependent subsystem entanglement entropy and renormalization of correlations in the ground state. We also find some new applications of the wavelet transform as a compressed representation of ground states of QFTs which can be used to illustrate quantum phase transitions via fidelity overlap and holographic entanglement of purification.

AB - Quantum field theory (QFT) describes nature using continuous fields, but physical properties of QFT are usually revealed in terms of measurements of observables at a finite resolution. We describe a multiscale representation of free scalar bosonic and Ising model fermionic QFTs using wavelets. Making use of the orthogonality and self-similarity of the wavelet basis functions, we demonstrate some well-known relations such as scale-dependent subsystem entanglement entropy and renormalization of correlations in the ground state. We also find some new applications of the wavelet transform as a compressed representation of ground states of QFTs which can be used to illustrate quantum phase transitions via fidelity overlap and holographic entanglement of purification.

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SN - 2470-0010

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Entanglement in quantum field theory via wavelet representations

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