A Thin Film Model for Meniscus Evolution

IF 1.2 3区数学 Q2 MATHEMATICS, APPLIED

Journal of Mathematical Fluid Mechanics Pub Date : 2024-09-21 DOI:10.1007/s00021-024-00893-0

Amrita Ghosh, Juan J. L. Velázquez

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Abstract

In this paper, we discuss a particular model arising from sinking of a rigid solid into a thin film of liquid, i.e. a liquid contained between two solid surfaces and part of the liquid surface is in contact with the air. The liquid is governed by Navier–Stokes equation, while the contact point, i.e. where the gas, liquid and solid meet, is assumed to be given by a constant, non-zero contact angle. We consider a scaling limit of the liquid thickness (lubrication approximation) and the contact angle between the liquid–solid and the liquid–gas interfaces close to \(\pi \). This resulting model is a free boundary problem for the equation \(h_t + (h^3h_{xxx})_x = 0\), for which we have \(h>0\) at the contact point (different from the usual thin film equation with \(h=0\) at the contact point). We show that this fourth order quasilinear (non-degenerate) parabolic equation, together with the so-called partial wetting condition at the contact point, is well-posed. Furthermore, the contact point in our thin film equation can actually move, contrary to the classical thin film equation for a droplet arising from the no-slip condition. Additionally, we show the global stability of steady state solutions in a periodic setting.

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半月板演变的薄膜模型

在本文中，我们讨论了刚性固体沉入液体薄膜所产生的一个特殊模型，即液体包含在两个固体表面之间，且部分液体表面与空气接触。液体受纳维-斯托克斯方程控制，而接触点，即气体、液体和固体的交汇点，则假定为一个恒定的非零接触角。我们考虑了液体厚度的缩放极限（润滑近似），以及液-固和液-气界面之间接近于 \（\pi \）的接触角。由此产生的模型是方程 \(h_t + (h^3h_{xxx})_x = 0\) 的自由边界问题，我们在接触点有 \(h>0\)（不同于通常的薄膜方程，在接触点有 \(h=0\)）。我们证明，这个四阶准线性（非退化）抛物线方程，加上接触点处的所谓部分润湿条件，可以很好地求解。此外，我们的薄膜方程中的接触点实际上是可以移动的，这与由无滑动条件产生的液滴经典薄膜方程相反。此外，我们还展示了周期性设置下稳态解的全局稳定性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Mathematical Fluid Mechanics 物理-力学

CiteScore

2.00

自引率

15.40%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal of Mathematical Fluid Mechanics (JMFM)is a forum for the publication of high-quality peer-reviewed papers on the mathematical theory of fluid mechanics, with special regards to the Navier-Stokes equations. As an important part of that, the journal encourages papers dealing with mathematical aspects of computational theory, as well as with applications in science and engineering. The journal also publishes in related areas of mathematics that have a direct bearing on the mathematical theory of fluid mechanics. All papers will be characterized by originality and mathematical rigor. For a paper to be accepted, it is not enough that it contains original results. In fact, results should be highly relevant to the mathematical theory of fluid mechanics, and meet a wide readership.