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Bibliographic Details
Main Authors: Li, Xingsheng, Li, Jing
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2402.05505
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author Li, Xingsheng
Li, Jing
author_facet Li, Xingsheng
Li, Jing
contents The linear instability of Faraday waves in Hele-Shaw cells is investigated with consideration of the viscosity of fluids after gap-averaging the governing equations due to the damping from two lateral walls and the dynamic behavior of contact angle. A new hydrodynamic model is thus derived and solved semi-analytically. The contribution of viscosity to critical acceleration amplitude is slight compared to other factors associated with dissipation, and the potential flow theory is sufficient to describe onset based on the present study, but the rotational component of velocity can change the timing of onset largely, which paradoxically comes from the viscosity. The model degenerates into a novel damped Mathieu equation if the viscosity is dropped with two damping terms referring to the gap-averaged damping and dissipation from dynamic contact angle, respectively. The former increases when the gap size decreases, and the latter grows as frequency rises. When it comes to the dispersion relation of Faraday waves, an unusual detuning emerges due to the imaginary part of the gap-averaged damping.
format Preprint
id arxiv_https___arxiv_org_abs_2402_05505
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle The stability analysis based on viscous theory of Faraday waves in Hele-Shaw cells
Li, Xingsheng
Li, Jing
Fluid Dynamics
The linear instability of Faraday waves in Hele-Shaw cells is investigated with consideration of the viscosity of fluids after gap-averaging the governing equations due to the damping from two lateral walls and the dynamic behavior of contact angle. A new hydrodynamic model is thus derived and solved semi-analytically. The contribution of viscosity to critical acceleration amplitude is slight compared to other factors associated with dissipation, and the potential flow theory is sufficient to describe onset based on the present study, but the rotational component of velocity can change the timing of onset largely, which paradoxically comes from the viscosity. The model degenerates into a novel damped Mathieu equation if the viscosity is dropped with two damping terms referring to the gap-averaged damping and dissipation from dynamic contact angle, respectively. The former increases when the gap size decreases, and the latter grows as frequency rises. When it comes to the dispersion relation of Faraday waves, an unusual detuning emerges due to the imaginary part of the gap-averaged damping.
title The stability analysis based on viscous theory of Faraday waves in Hele-Shaw cells
topic Fluid Dynamics
url https://arxiv.org/abs/2402.05505