Saved in:
Bibliographic Details
Main Authors: Bouin, Émeric, Kanzler, Laura, Mouhot, Clément
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2405.05943
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910440585428992
author Bouin, Émeric
Kanzler, Laura
Mouhot, Clément
author_facet Bouin, Émeric
Kanzler, Laura
Mouhot, Clément
contents We present an extension of results in a previous paper by the first and the last author [PMP, 2022] about macroscopic limits of linear kinetic equations in (potentially) fractional regimes. More precisely, we develop a unified framework inspired by Ellis and Pinsky [J. Math. Pures Appl., 1975] for operators that preserve mass, momentum and energy, and have microscopic equilibrium with heavy tails (typically polynomial). This paper also generalizes one of Hittmeir and Merino [KRM, 2016] in a related framework. The main difficulty, that leads to our main contribution, is the understanding of the spectrum of the generator in the Fourier space, which is significantly complicated by the lack of spectral gap and the fat tails of the equilibrium. Indeed, the scaling of the eigenelements in the suitable macroscopic rescaling is subtle to handle. In particular, our study uncovered an interesting difference in scaling in the fractional regime, where the transversal wave eigenvalues converge faster to zero than the Boussinesq and acoustic wave eigenvalues.
format Preprint
id arxiv_https___arxiv_org_abs_2405_05943
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Quantitative fluid approximation in fractional regimes of transport equations with more invariants
Bouin, Émeric
Kanzler, Laura
Mouhot, Clément
Analysis of PDEs
60J60, 35Q84, 82C40, 35B27, 60K50, 60G52, 76P05
We present an extension of results in a previous paper by the first and the last author [PMP, 2022] about macroscopic limits of linear kinetic equations in (potentially) fractional regimes. More precisely, we develop a unified framework inspired by Ellis and Pinsky [J. Math. Pures Appl., 1975] for operators that preserve mass, momentum and energy, and have microscopic equilibrium with heavy tails (typically polynomial). This paper also generalizes one of Hittmeir and Merino [KRM, 2016] in a related framework. The main difficulty, that leads to our main contribution, is the understanding of the spectrum of the generator in the Fourier space, which is significantly complicated by the lack of spectral gap and the fat tails of the equilibrium. Indeed, the scaling of the eigenelements in the suitable macroscopic rescaling is subtle to handle. In particular, our study uncovered an interesting difference in scaling in the fractional regime, where the transversal wave eigenvalues converge faster to zero than the Boussinesq and acoustic wave eigenvalues.
title Quantitative fluid approximation in fractional regimes of transport equations with more invariants
topic Analysis of PDEs
60J60, 35Q84, 82C40, 35B27, 60K50, 60G52, 76P05
url https://arxiv.org/abs/2405.05943