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Main Authors: Higaki, Mitsuo, Lu, Yulong, Zhuge, Jinping
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.11653
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author Higaki, Mitsuo
Lu, Yulong
Zhuge, Jinping
author_facet Higaki, Mitsuo
Lu, Yulong
Zhuge, Jinping
contents This paper is concerned with effective approximations and wall laws of viscous laminar flows in 3D pipes with randomly rough boundaries. The random roughness is characterized by the boundary oscillation scale $\varepsilon \ll 1 $ and a probability space with ergodicity quantified by functional inequalities. The results in this paper generalize the previous work for 2D channel flows with random Lipschitz boundaries to 3D pipe flows with random boundaries of John type. Moreover, we establish the optimal convergence rates and substantially improve the stochastic integrability obtained in the previous studies. Additionally, we prove a refined version of the Poiseuille's law in 3D pipes with random boundaries, which seems unaddressed in the literature. Our systematic approach combines several classical and recent ideas (particularly from homogenization theory), including the Saint-Venant's principle for pipe flows, the large-scale regularity theory over rough boundaries, and applications of functional inequalities.
format Preprint
id arxiv_https___arxiv_org_abs_2411_11653
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Wall laws for viscous flows in 3D randomly rough pipes: optimal convergence rates and stochastic integrability
Higaki, Mitsuo
Lu, Yulong
Zhuge, Jinping
Analysis of PDEs
Probability
This paper is concerned with effective approximations and wall laws of viscous laminar flows in 3D pipes with randomly rough boundaries. The random roughness is characterized by the boundary oscillation scale $\varepsilon \ll 1 $ and a probability space with ergodicity quantified by functional inequalities. The results in this paper generalize the previous work for 2D channel flows with random Lipschitz boundaries to 3D pipe flows with random boundaries of John type. Moreover, we establish the optimal convergence rates and substantially improve the stochastic integrability obtained in the previous studies. Additionally, we prove a refined version of the Poiseuille's law in 3D pipes with random boundaries, which seems unaddressed in the literature. Our systematic approach combines several classical and recent ideas (particularly from homogenization theory), including the Saint-Venant's principle for pipe flows, the large-scale regularity theory over rough boundaries, and applications of functional inequalities.
title Wall laws for viscous flows in 3D randomly rough pipes: optimal convergence rates and stochastic integrability
topic Analysis of PDEs
Probability
url https://arxiv.org/abs/2411.11653