Sliding drops in the diffuse interface model coupled to hydrodynamics

Thiele, Uwe; Velarde, Manuel G.; Neuffer, Kai; Bestehorn, Michael; Pomeau, Yves

doi:10.1103/physreve.64.061601

Cited by 82 publications

(115 citation statements)

References 43 publications

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“…Here we neglect any motions that may give rise to instabilities and focus on the dynamics of a contact line which is uniform in the transverse direction. This simplifying assumption is a rather common one and has been invoked in numerous related studies in the past (see, e.g., Hocking 1981;Thiele et al 2001Thiele et al , 2002Savva & Kalliadasis 2009Vellingiri et al 2011). It is also important to emphasize that film-like shapes can also be observed in solutions to (2.2) with (2.3) in the limit when gravity dominates capillarity, which causes the flattening of the droplet in the middle and the development of a pronounced bulge at the advancing edge (see also § 4).…”

Section: Modelmentioning

confidence: 99%

“…The coupling of contact line dynamics with long-wave models, such as (2.2) with (2.3), has a long history dating back to the studies of Greenspan (1978) and Hocking (1981), but it is also important to note that the same set of equations governs the motion of thin films flowing down an inclined plane (see Buckingham, Shearer & Bertozzi 2003;Kondic 2003, for more details on the derivation), which is a subject that has also been widely investigated by many authors since the seminal work of Huppert (1982). In this context, the droplet we consider can be viewed as a liquid ridge/rivulet which is known to be prone to instabilities in the transverse direction (see, e.g., Silvi & Dussan 1985;Troian et al 1989;Bertozzi & Brenner 1997;López, Miksis & Bankoff 1997;Hocking 1990;Kalliadasis 2000;Diez & Kondic 2001;Kondic 2003;Diez, González & Kondic 2012). Here we neglect any motions that may give rise to instabilities and focus on the dynamics of a contact line which is uniform in the transverse direction.…”

Section: Modelmentioning

confidence: 99%

“…To address the dynamic problem numerically, a broad range of methodologies were utilized, ranging from precursor film models (e.g. Thiele et al 2001Thiele et al , 2002Koh et al 2009), Lattice Boltzmann simulations (e.g. Dupuis & Yeomans 2006), to smoothed particle hydrodynamics (e.g.…”

Section: Introductionmentioning

confidence: 99%

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Droplet motion on inclined heterogeneous substrates

Savva

Kalliadasis

2013

J. Fluid Mech.

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We consider the static and dynamic behaviour of two-dimensional droplets on inclined heterogeneous substrates. We utilize an evolution equation for the droplet thickness based on the long-wave approximation of the Stokes equations in the presence of slip. Through a singular perturbation procedure, evolution equations for the location of the two moving fronts are obtained under the assumption of quasistatic dynamics. The deduced equations, which are verified by direct comparisons with numerical solutions to the governing equation, are scrutinized in a variety of dynamic and equilibrium settings. For example, we demonstrate the possibility for stick-slip dynamics, substrate-induced hysteresis, the uphill motion of the droplet for sufficiently strong chemical gradients and the existence of a critical inclination angle beyond which the droplet can no longer be supported at equilibrium. Where possible, analytical expressions are obtained for various quantities of interest, which are also verified by appropriate numerical experiments.

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Section: Modelmentioning

confidence: 99%

Section: Modelmentioning

confidence: 99%

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Droplet motion on inclined heterogeneous substrates

Savva

Kalliadasis

2013

J. Fluid Mech.

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“…Cahn-Hilliard or more generally phase-field energy functionals are for example applied in image processing such as inpainting (Bertozzi et al 2007). Wetting phenomena, of great interest in technological applications, especially motivated by recent developments in micro-fluidics, enjoy a wide-spread use of phase-field modelling (Pomeau 2001;Laurila et al 2008;Queralt-Martin et al 2011). Such phenomena have some intriguing features, including the appearance of hysteresis and non-locality, e.g.…”

Section: (A) Physical Motivationmentioning

confidence: 99%

Upscaled phase-field models for interfacial dynamics in strongly heterogeneous domains

et al. 2012

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We derive a new, effective macroscopic Cahn-Hilliard equation whose homogeneous free energy is represented by fourth-order polynomials, which form the frequently applied double-well potential. This upscaling is done for perforated/strongly heterogeneous domains. To the best knowledge of the authors, this seems to be the first attempt of upscaling the Cahn-Hilliard equation in such domains. The new homogenized equation should have a broad range of applicability owing to the well-known versatility of phase-field models. The additionally introduced feature of systematically and reliably accounting for confined geometries by homogenization allows for new modelling and numerical perspectives in both science and engineering. Our results are applied to wetting dynamics in porous media and to a single channel with strongly heterogeneous walls.

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“…Examples are falling drops on an inclined plane due to gravity 8,9,10 or the motion of droplets on a rotating disk due to centrifugal forces. In these cases much attention has been devoted to the onset of motion and the changes of the shape of the droplets and their instabilities in response to strong body forces.…”

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confidence: 99%

Statics and dynamics of a cylindrical droplet under an external body force

Servantie

Müller

2008

The Journal of Chemical Physics

100

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We study the rolling and sliding motion of droplets on a corrugated substrate by Molecular Dynamics simulations. Droplets are driven by an external body force (gravity) and we investigate the velocity profile and dissipation mechanisms in the steady state. The cylindrical geometry allows us to consider a large range of droplet sizes. The velocity of small droplets with a large contact angle is dominated by the friction at the substrate and the velocity of the center of mass scales like the square root of the droplet size. For large droplets or small contact angles, however, viscous dissipation of the flow inside the volume of the droplet dictates the center of mass velocity that scales linearly with the size. We derive a simple analytical description predicting the dependence of the center of mass velocity on droplet size and the slip length at the substrate. In the limit of vanishing droplet velocity we quantitatively compare our simulation results to the predictions and good agreement without adjustable parameters is found.

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Sliding drops in the diffuse interface model coupled to hydrodynamics

Cited by 82 publications

References 43 publications

Droplet motion on inclined heterogeneous substrates

Droplet motion on inclined heterogeneous substrates

Upscaled phase-field models for interfacial dynamics in strongly heterogeneous domains

Statics and dynamics of a cylindrical droplet under an external body force

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