Issue 19, 2017

Dynamics of a multicomponent vesicle in shear flow

Abstract

We study the fully nonlinear, nonlocal dynamics of two-dimensional multicomponent vesicles in a shear flow with matched viscosity of the inner and outer fluids. Using a nonstiff, pseudo-spectral boundary integral method, we investigate dynamical patterns induced by inhomogeneous bending for a two phase system. Numerical results reveal that there exist novel phase-treading and tumbling mechanisms that cannot be observed for a homogeneous vesicle. In particular, unlike the well-known steady tank-treading dynamics characterized by a fixed inclination angle, here the phase-treading mechanism leads to unsteady periodic dynamics with an oscillatory inclination angle. When the average phase concentration is around 1/2, we observe tumbling dynamics even for very low shear rate, and the excess length required for tumbling is significantly smaller than the value for the single phase case. We summarize our results in phase diagrams in terms of the excess length, shear rate, and concentration of the soft phase. These findings go beyond the well known dynamical regimes of a homogeneous vesicle and highlight the level of complexity of vesicle dynamics in a fluid due to heterogeneous material properties.

Graphical abstract: Dynamics of a multicomponent vesicle in shear flow

Supplementary files

Article information

Article type
Paper
Submitted
31 Oct 2016
Accepted
14 Apr 2017
First published
25 Apr 2017

Soft Matter, 2017,13, 3521-3531

Dynamics of a multicomponent vesicle in shear flow

K. Liu, G. R. Marple, J. Allard, S. Li, S. Veerapaneni and J. Lowengrub, Soft Matter, 2017, 13, 3521 DOI: 10.1039/C6SM02452A

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