Coupling of finite element and boundary integral methods for a capsule in a Stokes flow

Walter, J.; Salsac, Anne‐Virginie; Barthès-Biesel, Dominique; Tallec, Patrick Le

doi:10.1002/nme.2859

Cited by 141 publications

(167 citation statements)

References 36 publications

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“…Studies of capsules in fluid flow have been conducted with different membrane constitutive laws, including Hookean (Beale & Strain 2008), neo-Hookean or Skalak (Walter et al 2010), and area-incompressible or inextensible membranes (Veerapaneni et al 2009). Different numerical methods have also been used, such as boundary integral and immersed boundary methods.…”

Section: Introductionmentioning

confidence: 99%

“…For values of the capillary number with Ca < Ca L or Ca > Ca H , compressive stresses develop in at least one of the two principal elastic tensions on the interface (see also Barthès-Biesel 1980), and when this occurs the evolution problem becomes highly unstable and the numerical method fails. Later work (Walter et al 2010) using a finiteelement method for the membrane obtains stable steady solutions even when compressive stresses are present. The greater stability of the finite-element method is thought to be due to numerical regularization.…”

Section: Introductionmentioning

confidence: 99%

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

2012

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Elastic capsules occur in nature in the form of cells and vesicles and are manufactured for biomedical applications. They are widely modelled, but there are few analytical results. In this paper, complex variable techniques are used to derive semi-analytical solutions for the steady-state response and time-dependent evolution of two-dimensional elastic capsules with an inviscid interior in Stokes flow. This provides a complete picture of the steady response of initially circular capsules in linear strain and shear flows as a function of the capillary number Ca. The analysis is complemented by spectrally accurate numerical computations of the time-dependent evolution. An imposed nonlinear strain that models the far-field velocity in Taylor's four-roller mill is found to lead to cusped steady shapes at a critical capillary number Ca c for Hookean capsules. Numerical simulation of the time-dependent evolution for Ca > Ca c shows the development of finite-time cusp singularities. The dynamics immediately prior to cusp formation are asymptotically self-similar, and the similarity exponents are predicted analytically and confirmed numerically. This is compelling evidence of finite-time singularity formation in fluid flow with elastic interfaces.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

2012

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“…The numerical method, a coupling of the boundary integral method and finite element method, was developed by Walter et al [8] to simulate the motion of capsules in an infinite shear flow.…”

Section: Methodsmentioning

confidence: 99%

Boundary element analysis of deformation and movement of a capsule and a red blood cell close to the wall

Nix

Imai

Ishikawa

et al. 2012

WIT Transactions on Modelling and Simulation

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A capsule is defined as a liquid drop enclosed by an elastic membrane. The study of capsule behavior near a stationary surface has a number of biological applications, such as red blood cells in the cardiovascular system. However, near-wall behavior of capsules has not been established well. In this study, we investigate the motion of initially spherical and biconcave capsules in simple shear flow near an infinite plane using a boundary integral method coupled to a finite element method. We find that the deformation of a capsule depends on its initial shape, orientation, and capillary number (Ca). However, the lift velocity of a capsule is dependent on its steady state deformation and distance from the wall. The dependence of lift velocity on deformation may help to explain phenomena such as leukocyte margination.

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“…In the present study, we follow the discretized method developed by Walter et al [3]. The membrane mechanics is solved by discretizing the equation (1) to finite element (FE) matrix.…”

Section: Discretizationmentioning

confidence: 99%

“…The BE method, which is used in the present work, is the most accurate method to simulate the motion of capsules, since the method directly treats jump condition at the membrane without any interpolation.Various studies have been conducted to simulate the detailed motion of capsules using this method, such as deformation of single capsule in shear flow [1] and interaction of two capsules [2]. Recently, Walter et al [3] proposed a coupling method of the BE method with the finite element (FE) method of membrane mechanics to improve the stability of the simulation. However, the analyzing scale of pervious studies was still limited in few capsules, because of heavy computational load of BE method.…”

Section: Introductionmentioning

confidence: 99%

Boundary element analysis of the multi-capsule flow using an ultra-high speed GPGPU computation

Matsunaga¹,

Imai²,

Ishikawa³

et al. 2012

WIT Transactions on Modelling and Simulation

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A capsule is a liquid drop enclosed by a thin membrane. Understanding the mechanics of capsule suspension is important in a variety of applications. However, computational time is still a barrier against successful simulations for dense suspension of capsules. We have developed an ultra-high speed computation method based on Graphics Processing Unit (GPU) computing for simulating multicapsule flow.In the case of using single GPU, the performance achieves 1.20 TFlops that corresponds to a 550-fold speed up compared with a CPU core. We also developed an algorithm of multi GPUs that hide data communication by overlapping with computational time. Since our method enables us to simulate from one to a few hundred capsules in a realistic computational time, the method could be a powerful solution for simulating the capsule suspension.

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Coupling of finite element and boundary integral methods for a capsule in a Stokes flow

Cited by 141 publications

References 36 publications

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

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

Boundary element analysis of deformation and movement of a capsule and a red blood cell close to the wall

Boundary element analysis of the multi-capsule flow using an ultra-high speed GPGPU computation

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