Ground State Energy of Dilute Bose Gases in 1D

Johannes Agerskov; Robin Reuvers; Jan Philip Solovej

doi:10.1007/s00220-024-05193-2

Ground State Energy of Dilute Bose Gases in 1D

Johannes Agerskov^*, Robin Reuvers, Jan Philip Solovej

^*Corresponding author for this work

Department of Mathematical Sciences

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

We study the ground state energy of a gas of 1D bosons with density ρ, interacting through a general, repulsive 2-body potential with scattering length a, in the dilute limit ρ|a|≪1. The first terms in the expansion of the thermodynamic energy density are (π2ρ3/3)(1+2ρa), where the leading order is the 1D free Fermi gas. This result covers the Tonks–Girardeau limit of the Lieb–Liniger model as a special case, but given the possibility that a>0, it also applies to potentials that differ significantly from a delta function. We include extensions to spinless fermions and 1D anyonic symmetries, and discuss an application to confined 3D gases.

Original language	English
Article number	27
Journal	Communications in Mathematical Physics
Volume	406
Issue number	2
Number of pages	41
ISSN	0010-3616
DOIs	https://doi.org/10.1007/s00220-024-05193-2
Publication status	Published - 2025

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© The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature 2024.

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Cite this

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title = "Ground State Energy of Dilute Bose Gases in 1D",

abstract = "We study the ground state energy of a gas of 1D bosons with density ρ, interacting through a general, repulsive 2-body potential with scattering length a, in the dilute limit ρ|a|≪1. The first terms in the expansion of the thermodynamic energy density are (π2ρ3/3)(1+2ρa), where the leading order is the 1D free Fermi gas. This result covers the Tonks–Girardeau limit of the Lieb–Liniger model as a special case, but given the possibility that a>0, it also applies to potentials that differ significantly from a delta function. We include extensions to spinless fermions and 1D anyonic symmetries, and discuss an application to confined 3D gases.",

author = "Johannes Agerskov and Robin Reuvers and Solovej, {Jan Philip}",

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AU - Agerskov, Johannes

AU - Reuvers, Robin

AU - Solovej, Jan Philip

N1 - Publisher Copyright: © The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature 2024.

PY - 2025

Y1 - 2025

N2 - We study the ground state energy of a gas of 1D bosons with density ρ, interacting through a general, repulsive 2-body potential with scattering length a, in the dilute limit ρ|a|≪1. The first terms in the expansion of the thermodynamic energy density are (π2ρ3/3)(1+2ρa), where the leading order is the 1D free Fermi gas. This result covers the Tonks–Girardeau limit of the Lieb–Liniger model as a special case, but given the possibility that a>0, it also applies to potentials that differ significantly from a delta function. We include extensions to spinless fermions and 1D anyonic symmetries, and discuss an application to confined 3D gases.

AB - We study the ground state energy of a gas of 1D bosons with density ρ, interacting through a general, repulsive 2-body potential with scattering length a, in the dilute limit ρ|a|≪1. The first terms in the expansion of the thermodynamic energy density are (π2ρ3/3)(1+2ρa), where the leading order is the 1D free Fermi gas. This result covers the Tonks–Girardeau limit of the Lieb–Liniger model as a special case, but given the possibility that a>0, it also applies to potentials that differ significantly from a delta function. We include extensions to spinless fermions and 1D anyonic symmetries, and discuss an application to confined 3D gases.

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DO - 10.1007/s00220-024-05193-2

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JO - Communications in Mathematical Physics

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