Large Deviation Principles for Hypersingular Riesz Gases

Douglas P. Hardin; Thomas Leblé; Edward B. Saff; Sylvia Serfaty

doi:10.1007/s00365-018-9431-9

Large Deviation Principles for Hypersingular Riesz Gases

Douglas P. Hardin
, Thomas Leblé
, Edward B. Saff
, Sylvia Serfaty

Vanderbilt University
Courant Institute of Mathematical Sciences
Institut Universitaire de France
CNRS

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We study N-particle systems in R^d whose interactions are governed by a hypersingular Riesz potential | x- y| ^-^s, s> d, and subject to an external field. We provide both macroscopic results as well as microscopic results in the limit as N→ ∞ for random point configurations with respect to the associated Gibbs measure at scaled inverse temperature β. We show that a large deviation principle holds with a rate function of the form ‘β-Energy + Entropy’, yielding that the microscopic behavior (on the scale N^-¹^/^d) of such N-point systems is asymptotically determined by the minimizers of this rate function. In contrast to the asymptotic behavior in the integrable case s< d, where on the macroscopic scale N-point empirical measures have limiting density independent of β, the limiting density for s> d is strongly β-dependent.

langue originale	Anglais
Pages (de - à)	61-100
Nombre de pages	40
journal	Constructive Approximation
Volume	48
Numéro de publication	1
Les DOIs	https://doi.org/10.1007/s00365-018-9431-9
état	Publié - 1 août 2018
Modification externe	Oui

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title = "Large Deviation Principles for Hypersingular Riesz Gases",

abstract = "We study N-particle systems in Rd whose interactions are governed by a hypersingular Riesz potential | x- y| -s, s> d, and subject to an external field. We provide both macroscopic results as well as microscopic results in the limit as N→ ∞ for random point configurations with respect to the associated Gibbs measure at scaled inverse temperature β. We show that a large deviation principle holds with a rate function of the form {\textquoteleft}β-Energy + Entropy{\textquoteright}, yielding that the microscopic behavior (on the scale N-1/d) of such N-point systems is asymptotically determined by the minimizers of this rate function. In contrast to the asymptotic behavior in the integrable case s< d, where on the macroscopic scale N-point empirical measures have limiting density independent of β, the limiting density for s> d is strongly β-dependent.",

keywords = "Empirical measures, Gibbs measure, Large deviation principle, Minimal energy, Riesz gases",

author = "Hardin, \{Douglas P.\} and Thomas Lebl{\'e} and Saff, \{Edward B.\} and Sylvia Serfaty",

note = "Publisher Copyright: {\textcopyright} 2018, Springer Science+Business Media, LLC, part of Springer Nature.",

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AU - Hardin, Douglas P.

AU - Leblé, Thomas

AU - Saff, Edward B.

AU - Serfaty, Sylvia

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N2 - We study N-particle systems in Rd whose interactions are governed by a hypersingular Riesz potential | x- y| -s, s> d, and subject to an external field. We provide both macroscopic results as well as microscopic results in the limit as N→ ∞ for random point configurations with respect to the associated Gibbs measure at scaled inverse temperature β. We show that a large deviation principle holds with a rate function of the form ‘β-Energy + Entropy’, yielding that the microscopic behavior (on the scale N-1/d) of such N-point systems is asymptotically determined by the minimizers of this rate function. In contrast to the asymptotic behavior in the integrable case s< d, where on the macroscopic scale N-point empirical measures have limiting density independent of β, the limiting density for s> d is strongly β-dependent.

AB - We study N-particle systems in Rd whose interactions are governed by a hypersingular Riesz potential | x- y| -s, s> d, and subject to an external field. We provide both macroscopic results as well as microscopic results in the limit as N→ ∞ for random point configurations with respect to the associated Gibbs measure at scaled inverse temperature β. We show that a large deviation principle holds with a rate function of the form ‘β-Energy + Entropy’, yielding that the microscopic behavior (on the scale N-1/d) of such N-point systems is asymptotically determined by the minimizers of this rate function. In contrast to the asymptotic behavior in the integrable case s< d, where on the macroscopic scale N-point empirical measures have limiting density independent of β, the limiting density for s> d is strongly β-dependent.

KW - Empirical measures

KW - Gibbs measure

KW - Large deviation principle

KW - Minimal energy

KW - Riesz gases

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Large Deviation Principles for Hypersingular Riesz Gases

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