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Bibliographic Details
Main Authors: Breit, D., Feireisl, E., Hofmanova, M., Mucha, P. B.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.10256
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author Breit, D.
Feireisl, E.
Hofmanova, M.
Mucha, P. B.
author_facet Breit, D.
Feireisl, E.
Hofmanova, M.
Mucha, P. B.
contents We study the compressible Navier-Stokes system driven by physically relevant transport noise, where the noise influences both the continuity and momentum equations. Our approach is based on transforming the system into a partial differential equation with random, time- and space-dependent coefficients. A key challenge arises from the fact that these coefficients are non-differentiable in time, rendering standard compactness arguments for the identification of the pressure inapplicable. To overcome this difficulty, we develop a novel multi-layer approximation scheme and introduce a precise localization strategy with respect to both the sample space and time variable. The limit pressure is then identified via the corresponding effective viscous flux identity. By means of stochastic compactness methods, particularly Skorokhod's representation theorem and its generalization by Jakubowski, we ensure the progressive measurability required to return to the original system. Our results broaden the applicability of transport noise models in fluid dynamics and offer new insights into the interaction between stochastic effects and compressibility.
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record_format arxiv
spellingShingle Compressible fluids excited by space-dependent transport noise
Breit, D.
Feireisl, E.
Hofmanova, M.
Mucha, P. B.
Analysis of PDEs
We study the compressible Navier-Stokes system driven by physically relevant transport noise, where the noise influences both the continuity and momentum equations. Our approach is based on transforming the system into a partial differential equation with random, time- and space-dependent coefficients. A key challenge arises from the fact that these coefficients are non-differentiable in time, rendering standard compactness arguments for the identification of the pressure inapplicable. To overcome this difficulty, we develop a novel multi-layer approximation scheme and introduce a precise localization strategy with respect to both the sample space and time variable. The limit pressure is then identified via the corresponding effective viscous flux identity. By means of stochastic compactness methods, particularly Skorokhod's representation theorem and its generalization by Jakubowski, we ensure the progressive measurability required to return to the original system. Our results broaden the applicability of transport noise models in fluid dynamics and offer new insights into the interaction between stochastic effects and compressibility.
title Compressible fluids excited by space-dependent transport noise
topic Analysis of PDEs
url https://arxiv.org/abs/2504.10256