The spatial distribution of gyrotactic swimming micro-organisms in laminar flow fields
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Publication:2891778
DOI10.1017/jfm.2011.198zbMath1241.76475OpenAlexW2117507222MaRDI QIDQ2891778
Graeme J. Thorn, R. N. Bearon, Andrew L. Hazel
Publication date: 15 June 2012
Published in: Journal of Fluid Mechanics (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1017/jfm.2011.198
Related Items (21)
Vertical dispersion of model microorganisms in horizontal shear flow ⋮ Centripetal focusing of gyrotactic phytoplankton ⋮ Gyrotactic trapping of micro-swimmers in simple shear flows: a study directly from the fundamental Smoluchowski equation ⋮ Effects of wind on transient dispersion of active particles in a free-surface wetland flow ⋮ Distribution of gyrotactic micro-organisms in complex three-dimensional flows. Part 1. Horizontal shear flow past a vertical circular cylinder ⋮ Dispersion of a gyrotactic micro-organism suspension in a vertical pipe: the buoyancy–flow coupling effect ⋮ Pre-asymptotic dispersion of active particles through a vertical pipe: the origin of hydrodynamic focusing ⋮ Confined run-and-tumble model with boundary aggregation: Long-time behavior and convergence to the confined Fokker–Planck model ⋮ Streamwise dispersion of soluble matter in solvent flowing through a tube ⋮ Gyrotactic swimmer dispersion in pipe flow: testing the theory ⋮ Transient dispersion process of active particles ⋮ Transport of a dilute active suspension in pressure-driven channel flow ⋮ Dispersion of gyrotactic micro-organisms in pipe flows ⋮ Bifurcation and stability of downflowing gyrotactic micro-organism suspensions in a vertical pipe ⋮ Helicoidal particles and swimmers in a flow at low Reynolds number ⋮ Shape matters: a Brownian microswimmer in a channel ⋮ Dispersion of active particles in confined unidirectional flows ⋮ Photo-bioconvection: towards light control of flows in active suspensions ⋮ Biased swimming cells do not disperse in pipes as tracers: A population model based on microscale behaviour ⋮ A local approximation model for macroscale transport of biased active Brownian particles in a flowing suspension ⋮ Gyrotactic bioconvection at pycnoclines
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