The spatial structure of electrostatically forced Faraday waves

Dehe, Sebastian; Hartmann, Maximilian; Bandopadhyay, Aditya; Hardt, Steffen

doi:10.1017/jfm.2022.163

Cited by 7 publications

(1 citation statement)

References 53 publications

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“…The main purpose of the experiments was to show that the data could be used to estimate surface tension by curve fitting models with different assumed surface tensions to the experimental data. A significant improvement of the experimental apparatus, now verifying the predicted wavelengths was produced by Dehe et al [33,34].…”

Section: (C) Some Experimental Comparisons-the Case Of Viscous Fluidsmentioning

confidence: 65%

Pattern formation in Faraday instability—experimental validation of theoretical models

Dinesh

Livesay

Ignatius

et al. 2023

Phil. Trans. R. Soc. A.

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Two types of resonance-derived interfacial instability are reviewed with a focus on recent work detailing the effect of side walls on interfacial mode discretization. The first type of resonance is the mechanical Faraday instability, and the second is electrostatic Faraday instability. Both types of resonance are discussed for the case of single-frequency forcing. In the case of mechanical Faraday instability, inviscid theory can forecast the modal forms that one might expect when viscosity is taken into account. Experiments show very favourable validation with theory for both modal forms and onset conditions. Lowering of gravity is predicted to shift smaller wavelengths or choppier modes to lower frequencies. This is also validated by experiments. Electrostatic resonant instability is shown to lead to a pillaring mode that occurs at low wavenumbers, which is akin to Rayleigh Taylor instability. As in the case of mechanical resonance, experiments show favourable validation with theoretical predictions of patterns. A stark difference between the two forms of resonance is the observation of a gradual rise in the negative detuning instability in the case of mechanical Faraday and a very sharp one in the case of electrostatic resonance. This article is part of the theme issue ‘New trends in pattern formation and nonlinear dynamics of extended systems’.

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Section: (C) Some Experimental Comparisons-the Case Of Viscous Fluidsmentioning

confidence: 65%

Pattern formation in Faraday instability—experimental validation of theoretical models

Dinesh

Livesay

Ignatius

et al. 2023

Phil. Trans. R. Soc. A.

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Electrostatically induced Faraday instability of thin film with spontaneous odd viscosity

Chu

Jian

2023

Journal of Non-Newtonian Fluid Mechanics

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Faraday instability of non-Newtonian fluids under low-frequency vertical harmonic vibration

Huo

Wang

2022

Physics of Fluids

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Resonance Acoustic Mixing® (RAM) technology applies an external low-frequency vertical harmonic vibration to convey and mix the non-Newtonian fluid across space. However, although this method is used for various applications, its mechanism is yet not well understood. In this paper, we investigate the Faraday instability of power-law non-Newtonian fluids in RAM utilizing theory and simulations. According to the Floquet analysis and the dimensionless Mathieu equation, the critical stable region besides the stable region and the unstable region is discovered. Based on the numerical solutions of the two-dimensional incompressible Euler equations for a prototype Faraday instability flow, the temporal evolution of the surface displacement and the mechanism of Faraday waves for two cases are explored physically. For the low forcing displacement, there are only stable and critical stable regions. The surface deformation increases linearly and then enters the steady-state in which the fluctuation frequency is twice the vertical harmonic vibration. For the large forcing displacement, there are only stable and unstable regions. Under the effect of the inertial force, both cases have a sudden variation after the brief stabilization period. Furthermore, a ligament structure is observed, which signals that the surface is destabilized. In addition, a band-like pressure minimum distribution below the interface is formed. The fluid flows from the bottom to the crest portion to balance the pressure difference, which raises the crest.

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The spatial structure of electrostatically forced Faraday waves

Cited by 7 publications

References 53 publications

Pattern formation in Faraday instability—experimental validation of theoretical models

Pattern formation in Faraday instability—experimental validation of theoretical models

Electrostatically induced Faraday instability of thin film with spontaneous odd viscosity

Faraday instability of non-Newtonian fluids under low-frequency vertical harmonic vibration

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