Understanding the Onset of Oscillatory Swimming in Microchannels

Self-propelled colloids (swimmers) in confining geometries follow trajectories determined by hydrodynamic interactions with the bounding surfaces. However, typically these interactions are ignored or truncated to lowest order. We demonstrate that higher-order hydrodynamic moments cause rod-like swim...

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Veröffentlicht in:	arXiv.org 2016-05
Hauptverfasser:	de Graaf, Joost, Arnold J T M Mathijssen, Fabritius, Marc, Menke, Henri, Holm, Christian, Shendruk, Tyler N
Format:	Artikel
Sprache:	eng
Schlagworte:	Computer simulation Confining Lubrication Microchannels Parallel plates Physics - Fluid Dynamics Physics - Soft Condensed Matter Quadrupoles Swimming Trajectories
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description	Self-propelled colloids (swimmers) in confining geometries follow trajectories determined by hydrodynamic interactions with the bounding surfaces. However, typically these interactions are ignored or truncated to lowest order. We demonstrate that higher-order hydrodynamic moments cause rod-like swimmers to follow oscillatory trajectories in quiescent fluid between two parallel plates, using a combination of lattice-Boltzmann simulations and far-field calculations. This behavior occurs even far from the confining walls and does not require lubrication results. We show that a swimmer's hydrodynamic quadrupole moment is crucial to the onset of the oscillatory trajectories. This insight allows us to develop a simple model for the dynamics near the channel center based on these higher hydrodynamic moments, and suggests opportunities for trajectory-based experimental characterization of swimmers' hydrodynamic properties.
doi_str_mv	10.48550/arxiv.1605.00984
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subjects	Computer simulation Confining Lubrication Microchannels Parallel plates Physics - Fluid Dynamics Physics - Soft Condensed Matter Quadrupoles Swimming Trajectories
title	Understanding the Onset of Oscillatory Swimming in Microchannels
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