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Main Authors: Molinet, Luc, Talhouk, Raafat
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.04711
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author Molinet, Luc
Talhouk, Raafat
author_facet Molinet, Luc
Talhouk, Raafat
contents The Boussinesq-Peregrine system is derived from the water waves system in presence of topographic variation under the hypothesis of shallowness and small amplitude regime. The system becomes significantly simpler (at least in the mathematical sens) under the hypothesis of small topographic variation. In this work we study the long time and global well-posedness of the Boussinesq-Peregrine system. We start by showing the intermediate time well-posedness in the case of general topography (i.e. the amplitude of the bottom graph $β=O(1)$). The novelty resides in the functional setting, $H^s({\mathbb R}), \, s> \frac {1} {2}$. Then we show our main result establishing that the global existence result obtained in Molinet-Talhouk-Zaiter in the flat bottom case is still valid for the Boussinesq-Peregrine system under the hypothesis of small amplitude bottom variation (i.e. $β=O(μ)$). More precisely we prove that this system is unconditionally globally well-posed in the Sobolev spaces of type $ H^s ({\mathbb R}), \, s> \frac {1} {2}$. Finally, we show the existence of a weak global solution in the Schonbek sense, i.e. existence of low regularity entropic solutions of the small bottom amplitude Boussinesq-Pelegrine equations emanating from $ u_0 \in H^1 $ and $ ζ_0 $ in an Orlicz class as weak limits of regular solutions.
format Preprint
id arxiv_https___arxiv_org_abs_2406_04711
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Global solutions for the one-dimensional Boussinesq-Peregrine system under small bottom variation
Molinet, Luc
Talhouk, Raafat
Analysis of PDEs
35Q35, 35L56, 35A1, 35B30
The Boussinesq-Peregrine system is derived from the water waves system in presence of topographic variation under the hypothesis of shallowness and small amplitude regime. The system becomes significantly simpler (at least in the mathematical sens) under the hypothesis of small topographic variation. In this work we study the long time and global well-posedness of the Boussinesq-Peregrine system. We start by showing the intermediate time well-posedness in the case of general topography (i.e. the amplitude of the bottom graph $β=O(1)$). The novelty resides in the functional setting, $H^s({\mathbb R}), \, s> \frac {1} {2}$. Then we show our main result establishing that the global existence result obtained in Molinet-Talhouk-Zaiter in the flat bottom case is still valid for the Boussinesq-Peregrine system under the hypothesis of small amplitude bottom variation (i.e. $β=O(μ)$). More precisely we prove that this system is unconditionally globally well-posed in the Sobolev spaces of type $ H^s ({\mathbb R}), \, s> \frac {1} {2}$. Finally, we show the existence of a weak global solution in the Schonbek sense, i.e. existence of low regularity entropic solutions of the small bottom amplitude Boussinesq-Pelegrine equations emanating from $ u_0 \in H^1 $ and $ ζ_0 $ in an Orlicz class as weak limits of regular solutions.
title Global solutions for the one-dimensional Boussinesq-Peregrine system under small bottom variation
topic Analysis of PDEs
35Q35, 35L56, 35A1, 35B30
url https://arxiv.org/abs/2406.04711