Creeping motion of a solid particle inside a spherical elastic cavity: II. Asymmetric motion

@article{Hoell2019CreepingMO,
  title={Creeping motion of a solid particle inside a spherical elastic cavity: II. Asymmetric motion},
  author={Christian Hoell and Hartmut L{\"o}wen and Andreas M. Menzel and Abdallah Daddi-Moussa-Ider},
  journal={The European Physical Journal E},
  year={2019},
  volume={42},
  pages={1-14}
}
Abstract.An analytical method is proposed for computing the low-Reynolds-number hydrodynamic mobility function of a small colloidal particle asymmetrically moving inside a large spherical elastic cavity, the membrane of which is endowed with resistance toward shear and bending. In conjunction with the results obtained in the first part (A. Daddi-Moussa-Ider, H. Löwen, S. Gekle, Eur. Phys. J. E 41, 104 (2018)), in which the axisymmetric motion normal to the surface of an elastic cavity is… 
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7 Citations

7 Citations

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References

SHOWING 1-10 OF 99 REFERENCES

Creeping motion of a solid particle inside a spherical elastic cavity

An analytical theory for the low-Reynolds-number motion of a solid particle moving inside a larger spherical elastic cavity which can be seen as a model system for a fluid vesicle finds that the particle self-mobility function is higher than that predicted inside a rigid no-slip cavity.

Hydrodynamic mobility of a solid particle near a spherical elastic membrane. II. Asymmetric motion.

Analytical expressions for the leading-order hydrodynamic mobility of a small solid particle undergoing motion tangential to a nearby large spherical capsule whose membrane possesses resistance toward shearing and bending derive a low-frequency peak in the particle self-mobility, resulting from the membrane normal displacement.

Hydrodynamic mobility of a sphere moving on the centerline of an elastic tube

Elastic channels are an important component of many soft matter systems, in which hydrodynamic interactions with confining membranes determine the behavior of particles in flow. In this work, we

Particle mobility between two planar elastic membranes: Brownian motion and membrane deformation

We study the motion of a solid particle immersed in a Newtonian fluid and confined between two parallel elastic membranes possessing shear and bending rigidity. The hydrodynamic mobility depends on

Hindered mobility of a particle near a soft interface.

  • T. Bickel
  • Physics
    Physical review. E, Statistical, nonlinear, and soft matter physics
  • 2007
The perturbative analysis allows us to express the explicit position and frequency dependence of the mobility for small particles in the low Reynolds number regime and recovers in the steady limit the result for a sphere near a perfectly flat interface.

Transient elastohydrodynamic drag on a particle moving near a deformable wall

We examine the prescribed time-dependent motion of a rigid particle (a sphere or a cylinder) moving in a viscous fluid close to a deformable wall. The fluid motion is described by a nonlinear

Membrane-induced hydroelastic migration of a particle surfing its own wave

While coupling between fluid flow and soft elastic surfaces is common in biology and engineering, an analytical description is challenging as it often involves non-linear dynamics. Here we show using

Particle motion between parallel walls: Hydrodynamics and simulation

The low-Reynolds-number motion of a single spherical particle between parallel walls is determined from the exact reflection of the velocity field generated by multipoles of the force density on the

Efficient and accurate simulations of deformable particles immersed in a fluid using a combined immersed boundary lattice Boltzmann finite element method

Equilibrium structure and diffusion in concentrated hydrodynamically interacting suspensions confined by a spherical cavity

The short- and long-time equilibrium transport properties of a hydrodynamically interacting suspension confined by a spherical cavity are studied via Stokesian dynamics simulations for a wide range
...