Drag force on a sphere moving toward an anisotropic superhydrophobic plane

Asmolov, Evgeny S.; Belyaev, Aleksey V.; Vinogradova, Olga I.

doi:10.1103/physreve.84.026330

Cited by 33 publications

(33 citation statements)

References 49 publications

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“…Since at short separations we observe f * → 0, one can conclude that slippage (which would lead to f * → 1/4 [20]) obviously does not mimic roughness when h is small, by overestimating the drag force. The same remark concerns effective superhydrophobic slippage where f * → 2(4 − 3φ)/(8 + 9φ − 9φ 2 ) [21] and is equal to 0.3 for this particular sample. Therefore, our experimental results are now compared with theoretical calculations made for an effective smooth plane shifted down from the top of the corrugations, i.e., by assuming Table I Table I we present the experimental values of s for different samples, and curves calculated with Eq.…”

Section: Resultsmentioning

confidence: 68%

Effective hydrodynamic boundary conditions for microtextured surfaces

et al. 2013

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Understanding the influence of topographic heterogeneities on liquid flows has become an important issue with the development of microfluidic systems, and more generally for the manipulation of liquids at the small scale. Most studies of the boundary flow past such surfaces have concerned poorly wetting liquids for which the topography acts to generate superhydrophobic slip. Here we focus on topographically patterned but chemically homogeneous surfaces, and measure a drag force on a sphere approaching a plane decorated with lyophilic microscopic grooves. A significant decrease in the force compared with predicted even for a superhydrophobic surface is observed. To quantify the force we use the effective no-slip boundary condition, which is applied at the imaginary smooth homogeneous isotropic surface located at an intermediate position between the top and bottom of grooves. We relate its location to a surface topology by a simple, but accurate analytical formula. Since grooves represent the most anisotropic surface, our conclusions are valid for any texture, and suggest rules for the rational design of topographically patterned surfaces to generate desired drag.

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Section: Resultsmentioning

confidence: 68%

Effective hydrodynamic boundary conditions for microtextured surfaces

et al. 2013

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“…In this experiment [31], the authors have assumed that the boundary slip is described by the Vinogradova equation shown above. More recently, Asmolov et al [34] showed that on textured superhydrophobic surfaces, the effective slip length is not independent of the distance in the drainage experiments. Asmolov et al [34] suggested a new expression to evaluate the slip length on textured superhydrophobic surfaces, and it will be useful to check such expressions in forthcoming AFM experiments.…”

Section: (D) Surface Force Apparatus Experimentsmentioning

confidence: 99%

Measurement of slip length on superhydrophobic surfaces

Maali

Bhushan

2012

Phil. Trans. R. Soc. A.

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In this paper, a review of different techniques used to measure the slip length on superhydrophobic surfaces with large slip length is presented. First, we present the theoretical models used to calculate the effective slip length on superhydrophobic surfaces in different configurations of liquid flow. Then, we present the different techniques used to measure the slip past these superhydrophobic surfaces: rheometry, particle image velocimetry, pressure drop, surface force apparatus and atomic force microscopy.

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“…1). As in most previous publications [7,12,15,20,29,[35][36][37], we model the superhydrophobic plate as a flat heterogeneous interface. In such a description, we neglect an additional mechanism for a dissipation connected with the meniscus curvature [15,38,39].…”

Section: Model and Governing Equationsmentioning

confidence: 99%

Effective slippage on superhydrophobic trapezoidal grooves

Zhou

Asmolov

Schmid

et al. 2013

The Journal of Chemical Physics

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We study the effective slippage on superhydrophobic grooves with trapezoidal cross-sections of various geometries (including the limiting cases of triangles and rectangular stripes), by using two complementary approaches. First, dissipative particle dynamics (DPD) simulations of a flow past such surfaces have been performed to validate an expression [E. S. Asmolov and O. I. Vinogradova, J. Fluid Mech. 706, 108 (2012)] that relates the eigenvalues of the effective slip-length tensor for one-dimensional textures. Second, we propose theoretical estimates for the effective slip length and calculate it numerically by solving the Stokes equation based on a collocation method. The comparison between the two approaches shows that they are in excellent agreement. Our results demonstrate that the effective slippage depends strongly on the area-averaged slip, the amplitude of the roughness, and on the fraction of solid in contact with the liquid. To interpret these results, we analyze flow singularities near slipping heterogeneities, and demonstrate that they inhibit the effective slip and enhance the anisotropy of the flow. Finally, we propose some guidelines to design optimal one-dimensional superhydrophobic surfaces, motivated by potential applications in microfluidics.

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Drag force on a sphere moving toward an anisotropic superhydrophobic plane

Cited by 33 publications

References 49 publications

Effective hydrodynamic boundary conditions for microtextured surfaces

Effective hydrodynamic boundary conditions for microtextured surfaces

Measurement of slip length on superhydrophobic surfaces

Effective slippage on superhydrophobic trapezoidal grooves

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