Semi-analytical solutions for two-dimensional elastic capsules in Stokes flow

Higley, Michael; Siegel, Michael; Booty, Michael R.

doi:10.1098/rspa.2012.0090

Cited by 7 publications

(19 citation statements)

References 35 publications

(63 reference statements)

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“…For all capsule hardness, this edge curvature shows a very fast (exponential-like) increase with the capsule elongation L c which is higher for the less-strain-hardening capsules (such as the Skalak C = 0.1 and neo-Hookean capsules) owing to their lamellar shape. It is of interest to note that Higley, Siegel & Booty (2012) also found that the steady-state edge curvature of Hookean two-dimensional capsules increases exponentially with the flow rate in extensional flows. This suggests that the existence of a very small (in particular, exponentially small) edge length scale is a general feature of capsules in strong extensional flows, facilitated by the development of very small membrane tensions at the capsule tips (Dodson & Dimitrakopoulos 2008, 2009Higley et al 2012).…”

Section: Effects Of Membrane Hardness On the Capsule Steady-state Promentioning

confidence: 97%

“…It is of interest to note that Higley, Siegel & Booty (2012) also found that the steady-state edge curvature of Hookean two-dimensional capsules increases exponentially with the flow rate in extensional flows. This suggests that the existence of a very small (in particular, exponentially small) edge length scale is a general feature of capsules in strong extensional flows, facilitated by the development of very small membrane tensions at the capsule tips (Dodson & Dimitrakopoulos 2008, 2009Higley et al 2012). Figure 7(b) shows the elongation dependence of the edge curvature C xz that characterizes the local edge length scale along the lateral z-axis.…”

Section: Effects Of Membrane Hardness On the Capsule Steady-state Promentioning

confidence: 97%

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Effects of membrane hardness and scaling analysis for capsules in planar extensional flows

Dimitrakopoulos

2014

J. Fluid Mech.

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In this paper, we investigate computationally the effects of membrane hardness on the dynamics of strain-hardening capsules in planar extensional Stokes flows. As the flow rate increases, all capsules reach elongated steady-state configurations but the cross-section of the more strain-hardening capsules preserves its elliptical shape while the less strain-hardening capsules become lamellar. The capsule deformation in strong extensional flows is accompanied with very pointed edges, i.e. large edge curvatures and thus small local edge length scales, which makes the current investigation a multilength interfacial dynamics problem. Our computational results for elongated strainhardening capsules are accompanied with a scaling analysis which provides physical insight on the extensional capsule dynamics. The two distinct capsule conformations we found, i.e. the slender spindle and lamellar capsules, are shown to represent two different types of steady-state extensional dynamics. The former are stabilized mainly via the membrane's shearing resistance and the latter via its area-dilatation resistance, associated with the elongation tension normal forces and thus both types differ from bubbles which are stabilized mainly via the lateral surface-tension normal forces. Our steady-state deformation results can be used to identify the elastic properties of a real capsule, i.e. the membrane's shear and area-dilatation moduli, utilizing a single experimental technique.

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Section: Effects Of Membrane Hardness On the Capsule Steady-state Promentioning

confidence: 97%

Section: Effects Of Membrane Hardness On the Capsule Steady-state Promentioning

confidence: 97%

Effects of membrane hardness and scaling analysis for capsules in planar extensional flows

Dimitrakopoulos

2014

J. Fluid Mech.

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“…They have been widely applied to compute the evolution of interfaces in potential flow, including the Kelvin-Helmholtz and Rayleigh-Taylor instabilities [5], [29], Hele-Shaw flow [26], [33], and water waves [7], [10]. They have also been extensively applied in Stokes flow to simulate the evolution of drops, bubbles, elastic capsules and vesicles [23], [42], [47], [50]. Boundary integral methods have been particularly important in micro-and bio-fluidic applications in which viscous forces are dominant over inertial ones.…”

Section: Introductionmentioning

confidence: 99%

“…Spectrally accurate discretizations of boundary integral formulations are now routinely implemented for 2D interfacial Stokes flow of drops and bubbles, see, e.g., [15], [30], [31], [40], [41], [53] and references therein. Spectral or high-order boundary integral methods for inextensible vesicles or elastic capsules are provided by [23], [37], [46], and [50]. High order accurate discretizations of axisymmetric and 3D flow problems, although still a subject of current research, are increasingly common [16], [48], [49], [51], [54].…”

Section: Introductionmentioning

confidence: 99%

Convergence of the boundary integral method for interfacial Stokes flow

Ambrose¹,

Siegel²,

Zhang³

2021

Preprint

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Boundary integral numerical methods are among the most accurate methods for interfacial Stokes flow, and are widely applied. They have the advantage that only the boundary of the domain must be discretized, which reduces the number of discretization points and allows the treatment of complicated interfaces. Despite their popularity, there is no analysis of the convergence of these methods for interfacial Stokes flow. In practice, the stability of discretizations of the boundary integral formulation can depend sensitively on details of the discretization and on the application of numerical filters. We present a convergence analysis of the boundary integral method for Stokes flow, focusing on a rather general method for computing the evolution of an elastic capsule, viscous drop, or inviscid bubble in 2D strain and shear flows. The analysis clarifies the role of numerical filters in practical computations.

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“…New experimental techniques have been developed to characterize elastic polymer membranes at liquid interfaces [14][15][16][17][18] . The rheology of such membranes has been studied in model geometries 15,17,[19][20][21][22][23] and also on real capsules in viscous flows to mimic real conditions of fabrication and use, through various experiments 16,[23][24][25][26] , theories [27][28][29] and simulations [30][31][32] . From this perspective, microfluidics is an ideal tool which allows to integrate measurement units directly in situ in the devices and to perform automated measurements on a large number of capsules.…”

Section: Introductionmentioning

confidence: 99%

Microfluidic probing of the complex interfacial rheology of multilayer capsules

et al. 2019

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Encapsulation of chemicals using polymer membranes enables to control their transport and delivery for applications such as agrochemistry or detergency. To rationalize the design of polymer capsules, it is necessary to understand how the membranes' mechanical properties control the transport and release of the cargo. In this article, we use microfluidics to produce model polymer capsules and study in situ their behavior in controlled elongational flows. Our model capsules are obtained by assembling polymer mono and hydrogen-bonded bilayers at the surface of an oil droplet in water. We also use microfluidics to probe in situ the mechanical properties of the membranes in a controlled elongational flow generated by introducing the capsules through a constriction and then in a larger chamber. The deformation and relaxation of the capsules depend on their composition and especially on the molecular interactions between the polymer chains that form the membranes and the anchoring energy of the first layer. We develop a model and perform numerical simulations to extract the main interfacial properties of the capsules from the measurement of their deformations in the microchannels.

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Semi-analytical solutions for two-dimensional elastic capsules in Stokes flow

Cited by 7 publications

References 35 publications

Effects of membrane hardness and scaling analysis for capsules in planar extensional flows

Effects of membrane hardness and scaling analysis for capsules in planar extensional flows

Convergence of the boundary integral method for interfacial Stokes flow

Microfluidic probing of the complex interfacial rheology of multilayer capsules

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