Shear-imposed falling film on a vertical moving plate with disrupted time-reversal

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Souradip Chattopadhyay , Ashutosh Bijalwan , Amar K. Gaonkar
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引用次数: 0

Abstract

We propose a mathematical model to study the stability and dynamics of a shear-imposed thin film flow on a vertical moving plate, incorporating the influence of odd viscosity. This odd viscosity effect is vital in conventional fluids when there is a disruption in time-reversal symmetry. Our motivation to study the dynamics with odd viscosity arises from recent studies (Kirkinis & Andreev, vol. 878, 2019, pp. 169–189; Chattopadhyay & Ji, vol. 455, 2023, pp. 133883) where the odd viscosity effectively reduces flow instabilities under different scenarios. Utilizing a long wave perturbation method, we derive a nonlinear evolution equation at the liquid–air interface, which is influenced by the motion of the vertical plate, imposed shear, odd viscosity, and inertia. We first perform a linear stability analysis of the model to get firsthand information on various flow parameters. Three distinct conditions for the vertical plate, quiescent, upward-moving, and downward-moving, are considered, accounting the imposed shear and odd viscosity. Additionally, employing the method of multiple scales, we conduct a weakly nonlinear stability analysis for the traveling wave solution of the evolution equation and explore its bifurcation analysis. The bifurcation analysis reveals the existence of subcritical unstable and supercritical stable zones for crucial flow parameters: odd viscosity, imposed shear, and motion of the vertical plate. Both linear and weakly nonlinear stability analyses demonstrate that the destabilizing effect induced by the upward motion of the vertical plate can be alleviated by applying uphill shear, while the destabilizing effect of downhill shear can be mitigated when the vertical plate is in a downward motion. Moreover, we define an eigenvalue problem that mirrors the Orr–Sommerfeld (OS) model for analyzing normal modes and identifying the critical Reynolds number. We investigate the dynamics of surface waves through numerical solutions of the OS eigenvalue problem using the Chebyshev spectral collocation method. We observe the consistent enhancement of stabilization in the presence of odd viscosity. In the low to moderate Reynolds number range, vertical plate motion and odd viscosity show similar behavior in OS analysis, while imposed shear exhibits distinct changes. The Benney-type model does not agree with the OS problem when the Reynolds number is moderate with or without the three key parameters: vertical plate motion, imposed shear, and odd viscosity. However, when the Reynolds number is low with or without the three key parameters: vertical plate motion, imposed shear, and odd viscosity, the Benney-type model agrees with the OS. Further, numerical simulations of the evolution equation corroborate the results obtained from linear stability, weakly nonlinear stability, and OS analyses. Finally, the Hopf bifurcation analysis of the fixed point reveals that the wave speed is influenced by both the motion of the plate and the imposed shear while it remains independent of odd viscosity.

垂直移动板上的剪切降膜,时间逆转紊乱
我们提出了一个数学模型来研究垂直运动板上的剪切薄膜流的稳定性和动力学,其中包含奇异粘度的影响。当时间反向对称性被破坏时,奇数粘度效应在传统流体中至关重要。我们研究奇数粘度动力学的动机来自近期的研究(Kirkinis & Andreev,vol. 878,2019,pp. 169-189;Chattopadhyay & Ji,vol. 455,2023,pp. 133883),在这些研究中,奇数粘度有效地降低了不同情况下的流动不稳定性。利用长波扰动法,我们推导出了液气界面的非线性演化方程,该方程受到竖板运动、外加剪切力、奇异粘度和惯性的影响。我们首先对模型进行了线性稳定性分析,以获得各种流动参数的第一手信息。考虑到外加剪切力和奇异粘度,我们对垂直板的静止、向上运动和向下运动三种不同情况进行了分析。此外,我们采用多尺度方法,对演化方程的行波解进行了弱非线性稳定性分析,并探讨了其分岔分析。分岔分析表明,在奇数粘度、外加剪切力和垂直板运动等关键流动参数下,存在亚临界不稳定区和超临界稳定区。线性和弱非线性稳定性分析表明,通过施加上坡剪切力,可减轻垂直板向上运动引起的失稳效应,而当垂直板向下运动时,可减轻下坡剪切力的失稳效应。此外,我们还定义了一个特征值问题,该问题反映了用于分析法向模式和确定临界雷诺数的奥尔-索默菲尔德(OS)模型。我们通过使用切比雪夫谱配位法对 OS 特征值问题进行数值求解,研究了表面波的动力学。我们观察到,在奇数粘度存在的情况下,稳定度持续增强。在中低雷诺数范围内,垂直板运动和奇数粘度在 OS 分析中表现出相似的行为,而外加剪切力则表现出明显的变化。当雷诺数为中等时,无论是否有三个关键参数:垂直板运动、外加剪切力和奇异粘度,本尼型模型都与 OS 问题不一致。然而,当雷诺数较低时,无论是否有三个关键参数:垂直板块运动、外加剪切力和奇数粘度,本尼型模型都与 OS 一致。此外,演化方程的数值模拟证实了线性稳定性、弱非线性稳定性和 OS 分析的结果。最后,对固定点的霍普夫分岔分析表明,波速受板块运动和外加剪切力的影响,而与奇数粘度无关。
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
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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