Derivation of Hartree's theory for generic mean-field Bose systems

Mathieu Lewin; Phan Thành Nam; Nicolas Rougerie

doi:10.1016/j.aim.2013.12.010

Derivation of Hartree's theory for generic mean-field Bose systems

Mathieu Lewin, Phan Thành Nam, Nicolas Rougerie

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

Abstract

In this paper we provide a novel strategy to prove the validity of Hartree's theory for the ground state energy of bosonic quantum systems in the mean-field regime. For the known case of trapped Bose gases, this can be shown using the strong quantum de Finetti theorem, which gives the structure of infinite hierarchies of k-particles density matrices. Here we deal with the case where some particles are allowed to escape to infinity, leading to a lack of compactness. Our approach is based on two ingredients: (1) a weak version of the quantum de Finetti theorem, and (2) geometric techniques for many-body systems. Our strategy does not rely on any special property of the interaction between the particles. In particular, our results cover those of Benguria-Lieb and Lieb-Yau for, respectively, bosonic atoms and boson stars.

Original language	English
Pages (from-to)	570-621
Number of pages	52
Journal	Advances in Mathematics
Volume	254
DOIs	https://doi.org/10.1016/j.aim.2013.12.010
Publication status	Published - 20 Mar 2014
Externally published	Yes

Keywords

Boson stars
Bosonic atoms
Hartree theory
Many-particle Hamiltonian
Mean-field regime
Quantum de Finetti theorem

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10.1016/j.aim.2013.12.010

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title = "Derivation of Hartree's theory for generic mean-field Bose systems",

abstract = "In this paper we provide a novel strategy to prove the validity of Hartree's theory for the ground state energy of bosonic quantum systems in the mean-field regime. For the known case of trapped Bose gases, this can be shown using the strong quantum de Finetti theorem, which gives the structure of infinite hierarchies of k-particles density matrices. Here we deal with the case where some particles are allowed to escape to infinity, leading to a lack of compactness. Our approach is based on two ingredients: (1) a weak version of the quantum de Finetti theorem, and (2) geometric techniques for many-body systems. Our strategy does not rely on any special property of the interaction between the particles. In particular, our results cover those of Benguria-Lieb and Lieb-Yau for, respectively, bosonic atoms and boson stars.",

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author = "Mathieu Lewin and Nam, \{Phan Th{\`a}nh\} and Nicolas Rougerie",

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T1 - Derivation of Hartree's theory for generic mean-field Bose systems

AU - Lewin, Mathieu

AU - Nam, Phan Thành

AU - Rougerie, Nicolas

PY - 2014/3/20

Y1 - 2014/3/20

N2 - In this paper we provide a novel strategy to prove the validity of Hartree's theory for the ground state energy of bosonic quantum systems in the mean-field regime. For the known case of trapped Bose gases, this can be shown using the strong quantum de Finetti theorem, which gives the structure of infinite hierarchies of k-particles density matrices. Here we deal with the case where some particles are allowed to escape to infinity, leading to a lack of compactness. Our approach is based on two ingredients: (1) a weak version of the quantum de Finetti theorem, and (2) geometric techniques for many-body systems. Our strategy does not rely on any special property of the interaction between the particles. In particular, our results cover those of Benguria-Lieb and Lieb-Yau for, respectively, bosonic atoms and boson stars.

AB - In this paper we provide a novel strategy to prove the validity of Hartree's theory for the ground state energy of bosonic quantum systems in the mean-field regime. For the known case of trapped Bose gases, this can be shown using the strong quantum de Finetti theorem, which gives the structure of infinite hierarchies of k-particles density matrices. Here we deal with the case where some particles are allowed to escape to infinity, leading to a lack of compactness. Our approach is based on two ingredients: (1) a weak version of the quantum de Finetti theorem, and (2) geometric techniques for many-body systems. Our strategy does not rely on any special property of the interaction between the particles. In particular, our results cover those of Benguria-Lieb and Lieb-Yau for, respectively, bosonic atoms and boson stars.

KW - Boson stars

KW - Bosonic atoms

KW - Hartree theory

KW - Many-particle Hamiltonian

KW - Mean-field regime

KW - Quantum de Finetti theorem

U2 - 10.1016/j.aim.2013.12.010

DO - 10.1016/j.aim.2013.12.010

M3 - Article

AN - SCOPUS:84892512325

SN - 0001-8708

VL - 254

SP - 570

EP - 621

JO - Advances in Mathematics

JF - Advances in Mathematics

ER -

Derivation of Hartree's theory for generic mean-field Bose systems

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Keywords

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