Pointwise space-time estimates of two-phase fluid model in dimension three

IF 1.1 3区数学 Q1 MATHEMATICS

Journal of Evolution Equations Pub Date : 2024-02-10 DOI:10.1007/s00028-024-00943-0

Zhigang Wu, Wenyue Zhou

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引用次数: 0

Abstract

We studied the pointwise space-time behavior of the classical solution to the Cauchy problem of two-phase fluid model derived by Choi (SIAM J Math Anal 48:3090–3122, 2016) when the initial data is sufficiently small and regular. This model is the compressible damped Euler system coupled with the compressible Naiver–Stokes system via a drag force. As we know, Liu and Wang (Commun Math Phys 196:145–173, 1998) verified that the solution of the compressible Naiver–Stokes system obeys the generalized Huygens’ principle, while Wang and Yang (J Differ Equ 173:410–450, 2001) verified the solution of the compressible Euler system does not obey the generalized Huygens’ principle due to the damped mechanism. In this paper, we proved that both of two densities and two momentums for the two-phase fluid model obey the generalized Huygens’ principle as that in Liu and Wang (Commun Math Phys 196:145–173, 1998). The main contribution is to overcome the difficulty of the non-conservation arising from the damped mechanism of the system. As a byproduct, we also extended \(L^2\)-estimate in Wu et al. (SIAM J Math Anal 52(6):5748–5774, 2020) to \(L^p\)-estimate with \(p>1\).

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三维两相流体模型的点时空估算

我们研究了Choi（SIAM J Math Anal 48:3090-3122，2016）导出的两相流体模型Cauchy问题经典解在初始数据足够小且规则时的点时空行为。该模型是通过阻力耦合的可压缩阻尼欧拉系统和可压缩 Naiver-Stokes 系统。我们知道，Liu 和 Wang（Commun Math Phys 196:145-173, 1998）验证了可压缩 Naiver-Stokes 系统的解服从广义惠更斯原理，而 Wang 和 Yang（J Differ Equ 173:410-450, 2001）验证了由于阻尼机制，可压缩欧拉系统的解不服从广义惠更斯原理。在本文中，我们证明了两相流体模型的两个密度和两个动量都遵守广义惠更斯原理，正如刘和王（Commun Math Phys 196:145-173, 1998）所言。我们的主要贡献在于克服了系统阻尼机制引起的不守恒难题。作为副产品，我们还将 Wu 等人 (SIAM J Math Anal 52(6):5748-5774, 2020) 中的\(L^2\)估计扩展到了\(p>1\)的\(L^p\)估计。

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来源期刊

Journal of Evolution Equations 数学-数学

CiteScore

2.30

自引率

7.10%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal of Evolution Equations (JEE) publishes high-quality, peer-reviewed papers on equations dealing with time dependent systems and ranging from abstract theory to concrete applications. Research articles should contain new and important results. Survey articles on recent developments are also considered as important contributions to the field. Particular topics covered by the journal are: Linear and Nonlinear Semigroups Parabolic and Hyperbolic Partial Differential Equations Reaction Diffusion Equations Deterministic and Stochastic Control Systems Transport and Population Equations Volterra Equations Delay Equations Stochastic Processes and Dirichlet Forms Maximal Regularity and Functional Calculi Asymptotics and Qualitative Theory of Linear and Nonlinear Evolution Equations Evolution Equations in Mathematical Physics Elliptic Operators