POSITIVE-DENSITY GROUND STATES OF THE GROSS–PITAEVSKII EQUATION

MATHIEU LEWIN; PHAN THÀN NAM

doi:10.2140/pmp.2025.6.647

POSITIVE-DENSITY GROUND STATES OF THE GROSS–PITAEVSKII EQUATION

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Abstract

We consider the nonlinear Gross–Pitaevskii equation at positive density, that is, for a bounded solution not tending to 0 at infinity. We focus on infinite ground states, which are by definition minimizers of the energy under local perturbations. When the Fourier transform of the interaction potential takes negative values we prove the existence of a phase transition at high density, where the constant solution ceases to be a ground state. The analysis requires mixing techniques from elliptic PDE theory and statistical mechanics, in order to deal with a large class of interaction potentials.

Original language	English
Pages (from-to)	647-731
Number of pages	85
Journal	Probability and Mathematical Physics
Volume	6
Issue number	3
DOIs	https://doi.org/10.2140/pmp.2025.6.647
Publication status	Published - 1 Jan 2025
Externally published	Yes

Keywords

Ginzburg–Landau theory
Gross–Pitaevskii equation
crystallization
phase transition

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10.2140/pmp.2025.6.647

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abstract = "We consider the nonlinear Gross–Pitaevskii equation at positive density, that is, for a bounded solution not tending to 0 at infinity. We focus on infinite ground states, which are by definition minimizers of the energy under local perturbations. When the Fourier transform of the interaction potential takes negative values we prove the existence of a phase transition at high density, where the constant solution ceases to be a ground state. The analysis requires mixing techniques from elliptic PDE theory and statistical mechanics, in order to deal with a large class of interaction potentials.",

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author = "MATHIEU LEWIN and NAM, \{PHAN TH{\`A}N\}",

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AB - We consider the nonlinear Gross–Pitaevskii equation at positive density, that is, for a bounded solution not tending to 0 at infinity. We focus on infinite ground states, which are by definition minimizers of the energy under local perturbations. When the Fourier transform of the interaction potential takes negative values we prove the existence of a phase transition at high density, where the constant solution ceases to be a ground state. The analysis requires mixing techniques from elliptic PDE theory and statistical mechanics, in order to deal with a large class of interaction potentials.

KW - Ginzburg–Landau theory

KW - Gross–Pitaevskii equation

KW - crystallization

KW - phase transition

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ER -

POSITIVE-DENSITY GROUND STATES OF THE GROSS–PITAEVSKII EQUATION

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Keywords

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