Long-wave Marangoni convection in a thin film heated from below

Shklyaev, Sergey; Alabuzhev, A. A.; Khenner, Mikhail

doi:10.1103/physreve.85.016328

Cited by 38 publications

(79 citation statements)

References 40 publications

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“…In contrast to [12] and several other papers [9,10,11,15,19,20] where longwave oscillatory convection is described by a pair of partial differential amplitude equations, the nonlinear dynamics for the thermocapillary and solutocapillary convection in a layer of binary mixture with a nondeformable free surface is governed by the solvability conditions for a certain set of linear nonhomogeneous equations [22]. In other words, the nonlinear dynamics is described by a set of nonlocal amplitude equations.…”

Section: Introductionmentioning

confidence: 90%

Oscillatory Longwave Marangoni Convection in a Binary Liquid. Part 2: Square Patterns

Shklyaev¹,

Nepomnyashchy²,

Oron³

2014

SIAM J. Appl. Math.

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As a natural extension for our recent work [SIAM J. Appl. Math., 73 (2013), pp. 2203-2223] we study pattern selection on a square lattice for longwave oscillatory Marangoni convection in a layer of binary liquid. In contrast to the previous studies dealing with weakly nonlinear dynamics of such systems only, in this recent work we developed a method based on the Fourier transform to describe the dynamics of finite-amplitude perturbations of both temperature and solute concentration. The method is then applied to study simple patterns on a rhombic lattice consisting of four or fewer interacting waves. The present paper is the first implementation of this theory to a problem with multiple interacting waves. In a wide range of parameters, alternating rolls (ARs) are the only stable pattern. For low values of the Schmidt number relevant for liquid semiconductors, a competition between ARs and traveling squares sets in and results in the emergence of a novel "asymmetric" pattern exhibiting properties of both traveling and standing regimes. Busse balloons for these patterns are found.

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Section: Introductionmentioning

confidence: 90%

Oscillatory Longwave Marangoni Convection in a Binary Liquid. Part 2: Square Patterns

Shklyaev¹,

Nepomnyashchy²,

Oron³

2014

SIAM J. Appl. Math.

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“…Multi-layer film configurations do not, however, guarantee oscillatory modes: for example, such instabilities were not obtained by Pototsky et al (2005) who investigated the dewetting dynamics of isothermal, ultrathin bilayers. Of particular interest to the present work are oscillatory instabilities reported by Shklyaev et al (2012) in a model of thin-film thermocapillary destabilization from below. While there are similarities between that work and the present, we point out one important difference: in Shklyaev et al (2012), the instability is driven by imposing a heat flux at the film-substrate interface; instead, in the present work we consider the full time-dependent heat-transfer in the substrate.…”

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confidence: 94%

Oscillatory thermocapillary instability of a film heated by a thick substrate

et al. 2019

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In this work we consider a new class of oscillatory instabilities that pertain to thermocapillary destabilization of a liquid film heated by a solid substrate. We assume the substrate thickness and substrate-film thermal conductivity ratio are large so that the effect of substrate thermal diffusion is retained at leading order in the long-wave approximation. As a result, system dynamics are described by a nonlinear partial differential equation for the film thickness that is nonlocally coupled to the full substrate heat equation. Perturbing about a steady quiescent state, we find that its stability is described by a non-self adjoint eigenvalue problem. We show that, under appropriate model parameters, the linearized eigenvalue problem admits complex eigenvalues that physically correspond to oscillatory (in time) instabilities of the thin film height. As the principal results of our work, we provide a complete picture of the susceptibility to oscillatory instabilities for different model parameters. Using this description, we conclude that oscillatory instabilities are more relevant experimentally for films heated by insulating substrates. Furthermore, we show that oscillatory instability where the fastest-growing (most unstable) wavenumber is complex, arises only for systems with sufficiently large substrate thicknesses.1 oscillatory instability can be a challenging task. Alternatively, the long wave approximation offers a convenient means to couple free surface deformation to other time-dependent physical processes of interest.Several authors have investigated oscillatory instabilities of thin liquid films in the context of the long-wave approximation. In many cases, e.g. Podolny et al. (2005) and Bestehorn and Borcia (2010), such instabilities originate from the coupling between the local thickness and bulk concentration of a film composed of a binary mixture. In addition to the bulk concentration dynamics, Morozov et al. (2014) investigated oscillatory instability with the added effect of absorption/desorption kinetics between interfacial and bulk film surfactant concentration. In other cases, oscillatory instabilities have been uncovered in multiple stacked layers of films, as described theoretically by coupled sets of film thickness evolution equations (Nepomnyashchy and Simanovskii (2007), Beerman and Brush (2007)). Multi-layer film configurations do not, however, guarantee oscillatory modes: for example, such instabilities were not obtained by Pototsky et al. (2005) who investigated the dewetting dynamics of isothermal, ultrathin bilayers. Of particular interest to the present work are oscillatory instabilities reported by Shklyaev et al. (2012) in a model of thin-film thermocapillary destabilization from below. While there are similarities between that work and the present, we point out one important difference: in Shklyaev et al. (2012), the instability is driven by imposing a heat flux at the film-substrate interface; instead, in the present work we consider the full time-dependent heat-transfer in the ...

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“…We have recently considered the influence of the feedback control on the oscillatory Marangoni instability in a thin film heated from below. We have shown that a linear control gain can delay the onset of instability [3] and a quadratic control gain can eliminate the subcritical excitation of instability [4]. The analysis of pattern formation was done for an infinite region, nonlinear interaction of the traveling waves was considered.…”

Section: Introductionmentioning

confidence: 99%

“…2. There we present a set of coupled amplitude equations which governs the evolution of the layer thickness and the temperature deviation under nonlinear feedback control [4]. In Sec.…”

Section: Introductionmentioning

confidence: 99%

Controlling of longwave oscillatory Marangoni patterns on a rhombic lattice

Samoilova

Nepomnyashchy

2021

Math. Model. Nat. Phenom.

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We apply nonlinear feedback control to govern the stability of long-wave oscillatory Marangoni patterns. We focus on the patterns caused by instability in thin liquid film heated from below with a deformable free surface. This instability emerges in the case of substrate of low thermal conductivity, when two monotonic long-wave instabilities, Pearson’s and deformational ones, are coupled. We provide weakly nonlinear analysis within the amplitude equations, which govern the evolution of the layer thickness and the temperature deviation. The action of the nonlinear feedback control on the nonlinear interaction of two standing waves is investigated. It is shown that quadratic feedback control can produce additional stable structures (standing rolls, standing squares and standing rectangles), which are subject to instability leading to traveling wave in the uncontrolled case.

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Long-wave Marangoni convection in a thin film heated from below

Cited by 38 publications

References 40 publications

Oscillatory Longwave Marangoni Convection in a Binary Liquid. Part 2: Square Patterns

Oscillatory Longwave Marangoni Convection in a Binary Liquid. Part 2: Square Patterns

Oscillatory thermocapillary instability of a film heated by a thick substrate

Controlling of longwave oscillatory Marangoni patterns on a rhombic lattice

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