Your search keyword '"Felix Rühle"' showing total 4 results

1. Collective Dynamics in a Monolayer of Squirmers Confined to a Boundary by Gravity

Author

Holger Stark, Jan-Timm Kuhr, and Felix Rühle

Subjects

Physics, Physics::Biological Physics, Strong gravity, Fluid Dynamics (physics.flu-dyn), FOS: Physical sciences, 02 engineering and technology, General Chemistry, Physics - Fluid Dynamics, Condensed Matter - Soft Condensed Matter, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Collision dynamics, Classical mechanics, Monolayer, Soft Condensed Matter (cond-mat.soft), Collective dynamics, ddc:532, 0210 nano-technology, Squirmer, Hydrodynamic flow

Abstract

We present a hydrodynamic study of a monolayer of squirmer model microswimmers confined to a boundary by strong gravity using the simulation method of multi-particle collision dynamics. The squirmers interact with each other via their self-generated hydrodynamic flow fields and thereby form a variety of fascinating dynamic states when density and squirmer type are varied. Weak pushers, neutral squirmers, and pullers have an upright orientation. With their flow fields they push neighbors away and thereby form a hydrodynamic Wigner fluid at lower densities. Furthermore, states of fluctuating chains and trimers, of kissing, and at large densities a global cluster exist. Finally, pushers at all densities can tilt against the wall normal and their in-plane velocities align to show swarming. It turns into chaotic swarming for strong pushers at high densities. We characterize all these states quantitatively., 11 pages, 14 figures, supplemental material not included

Published

2019

2. A flowing pair of particles in inertial microfluidics

Author

Felix Rühle, Holger Stark, and Christian Schaaf

Subjects

Inertial frame of reference, Microfluidics, Lattice Boltzmann methods, FOS: Physical sciences, 02 engineering and technology, Condensed Matter - Soft Condensed Matter, 010402 general chemistry, 01 natural sciences, Physics::Fluid Dynamics, symbols.namesake, ddc:530, Physics, Microchannel, Fluid Dynamics (physics.flu-dyn), Reynolds number, Physics - Fluid Dynamics, General Chemistry, Mechanics, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Hagen–Poiseuille equation, 530 Physik, 0104 chemical sciences, Lift (force), Fictitious force, symbols, Soft Condensed Matter (cond-mat.soft), 0210 nano-technology

Abstract

A flowing pair of particles in inertial microfluidics gives important insights into understanding and controlling the collective dynamics of particles like cells or droplets in microfluidic devices. They are applied in medical cell analysis and engineering. We study the dynamics of a pair of solid particles flowing through a rectangular microchannel using lattice Boltzmann simulations. We determine the inertial lift force profiles as a function of the two particle positions, their axial distance, and the Reynolds number. Generally, the profiles strongly differ between particles leading and lagging in flow and the lift forces are enhanced due to the presence of a second particle. At small axial distances, they are determined by viscous forces, while inertial forces dominate at large separations. We identify cross-streamline pairs as stable fixed points in the lift force profiles and argue that same-streamline configurations are only one-sided stable. Depending on the initial conditions, the two-particle lift forces in combination with the Poiseuille flow give rise to three types of unbound particle trajectories, called moving-apart, passing, and swapping, and one type of bound trajectory, where the particles perform damped oscillations towards the cross-stream line configuration. The damping rate scales with Reynolds number squared, since inertial forces are responsible for driving the particles to their steady-state positions.

Published

2019

3. Collective Sedimentation of Squirmers under Gravity

Author

Holger Stark, Johannes Blaschke, Felix Rühle, and Jan-Timm Kuhr

Subjects

Convection, Physics, Collective behavior, Gravity (chemistry), Physics::Biological Physics, Sedimentation (water treatment), Strong gravity, Fluid Dynamics (physics.flu-dyn), FOS: Physical sciences, General Chemistry, Mechanics, Physics - Fluid Dynamics, Condensed Matter - Soft Condensed Matter, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Physics::Fluid Dynamics, 0103 physical sciences, Fluid dynamics, Soft Condensed Matter (cond-mat.soft), 010306 general physics, Squirmer, Convection cell

Abstract

Active particles, which interact hydrodynamically, display a remarkable variety of emergent collective phenomena. We use squirmers to model spherical microswimmers and explore the collective behavior of thousands of them under the influence of strong gravity using the method of multi-particle collision dynamics for simulating fluid flow. The sedimentation profile depends on the ratio of swimming to sedimentation velocity as well as on the squirmer type. It shows close packed squirmer layers at the bottom and a highly dynamic region with exponential density dependence towards the top. The mean vertical orientation of the squirmers strongly depends on height. For swimming velocities larger than the sedimentation velocity, squirmers show strong convection in the exponential region. We quantify the strength of convection and the extent of convection cells by the vertical current density and its current dipole, which are large for neutral squirmers as well as for weak pushers and pullers., 8 pages, 11 figures

Published

2017

4. Effective substrate potentials with quasicrystalline symmetry depend on the size of the adsorbed particles

Author

Matthias Sandbrink, Holger Stark, Michael Schmiedeberg, and Felix Rühle

Subjects

Materials science, Condensed matter physics, Chemistry(all), Monte Carlo method, Biophysics, Quasicrystal, General Chemistry, Substrate (electronics), Surfaces and Interfaces, Symmetry (physics), Condensed Matter::Materials Science, Adsorption, Materials Science(all), Chemical physics, Particle, Molecule, General Materials Science, Translational symmetry, Biotechnology

Abstract

We explore the effective potential landscapes that extended particles experience when adsorbed on the surface of quasicrystals. Commonly, these are solids with long-ranged order but no translational symmetry. The effective potentials significantly depend on the size of the adsorbed particles. We show how changing the particle radius changes the so-called local isomorphism class of the effective quasicrystalline pattern. This means effective potentials for different particle sizes cannot directly be mapped onto each other. Our theoretical predictions are confirmed by Monte Carlo simulations. The results are important for colloidal particles with different sizes that are subjected to laser fields with quasicrystalline symmetry as well as for systems where extended molecules are deposited onto the surface of metallic quasicrystals.