Stability of slowly evaporating thin liquid films of binary mixtures

arXiv: Fluid Dynamics Pub Date : 2020-08-24 DOI:10.1103/physrevfluids.5.104007

R. Nazareth, G. Karapetsas, K. Sefiane, O. Matar, P. Valluri

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引用次数: 2

Abstract

We consider the evaporation of a thin liquid layer which consists of a binary mixture of volatile liquids. The mixture is on top of a heated substrate and in contact with the gas phase that consists of the same vapour as the binary mixture. The effect of thermocapillarity, solutocapillarity and the van der Waals interactions are considered. We derive the long-wave evolution equations for the free interface and the volume fraction that govern the two-dimensional stability of the layer subject to the above coupled mechanisms and perform a linear stability analysis. Our results demonstrate two modes of instabilities, a monotonic instability mode and an oscillatory instability mode. We supplement our results from stability analysis with transient simulations to examine the dynamics in the nonlinear regime and analyse how these instabilities evolve with time. More precisely we discuss how the effect of relative volatility along with the competition between thermal and solutal Marangoni effect defines the mode of instability that develops during the evaporation of the liquid layer due to preferential evaporation of one of the components.

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二元混合物缓慢蒸发薄液膜的稳定性

我们考虑由挥发性液体二元混合物组成的薄液体层的蒸发。混合物在加热的衬底上，与气相接触，气相由与二元混合物相同的蒸汽组成。考虑了热毛细作用、溶液毛细作用和范德华相互作用的影响。我们推导了在上述耦合机制作用下控制层二维稳定性的自由界面和体积分数的长波演化方程，并进行了线性稳定性分析。我们的结果证明了两种不稳定模式，一种单调不稳定模式和一种振荡不稳定模式。我们用暂态模拟来补充稳定性分析的结果，以检验非线性状态下的动力学，并分析这些不稳定性如何随时间演变。更准确地说，我们讨论了相对挥发性的影响以及热马兰戈尼效应和溶质马兰戈尼效应之间的竞争如何定义了在液体层蒸发过程中由于其中一种组分的优先蒸发而产生的不稳定性模式。

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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arXiv: Fluid Dynamics

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