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Paper detail

Lattice-Boltzmann Hydrodynamics of Anisotropic Active Matter

A plethora of active matter models exist that describe the behavior of self-propelled particles (or swimmers), both with and without hydrodynamics. However, there are few studies that consider shape-anisotropic swimmers and include hydrodynamic interactions. Here, we introduce a simple method to simulate self-propelled colloids interacting hydrodynamically in a viscous medium using the lattice-Boltzmann technique. Our model is based on raspberry-type viscous coupling and a force/counter-force formalism which ensures that the system is force free. We consider several anisotropic shapes and characterize their hydrodynamic multipolar flow field. We demonstrate that shape-anisotropy can lead to the presence of a strong quadrupole and octupole moments, in addition to the principle dipole moment. The ability to simulate and characterize these higher-order moments will prove crucial for understanding the behavior of model swimmers in confining geometries.

preprint2016arXivOpen access
Joost de GraafHenri MenkeArnold J. T. M. MathijssenMarc FabritiusChristian HolmTyler N. Shendruk
cond-mat.softphysics.flu-dyn
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Joost de GraafHenri MenkeArnold J. T. M. MathijssenMarc FabritiusChristian HolmTyler N. Shendruk

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