Gyrotactic trapping in laminar and turbulent Kolmogorov flow

Santamaria, Francesco; Lillo, F. De; Cencini, Massimo; Boffetta, G.

doi:10.1063/1.4900956

Cited by 42 publications

(56 citation statements)

References 46 publications

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“…active particles do not cluster at specific lateral positions or focus in flow. In contrast, in the presence of swimmer-wall hydrodynamic interactions [210], bottom-heaviness [213], phototaxis [214,215], flexible body shape [216], or viscoelastic flows [217], the dynamics becomes dissipative in the sense of dynamical systems and particles aggregate at specific locations in the flow (see also the discussions in [211,218,219]). Although swinging and tumbling trajectories in microchannel Poiseuille flow have been observed experimentally with biological microswimmers [212,220], they have not yet been confirmed in experiments with active colloids.…”

Section: Motion In External Fluid Flowmentioning

confidence: 99%

Emergent behavior in active colloids

Zöttl

Stark

2016

J. Phys.: Condens. Matter

500

559

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Active colloids are microscopic particles, which self-propel through viscous fluids by converting energy extracted from their environment into directed motion. We first explain how articial microswimmers move forward by generating near-surface flow fields via self-phoresis or the self-induced Marangoni effect. We then discuss generic features of the dynamics of single active colloids in bulk and in confinement, as well as in the presence of gravity, field gradients, and fluid flow. In the third part, we review the emergent collective behavior of active colloidal suspensions focussing on their structural and dynamic properties. After summarizing experimental observations, we give an overview on the progress in modeling collectively moving active colloids. While active Brownian particles are heavily used to study collective dynamics on large scales, more advanced methods are necessary to explore the importance of hydrodynamic and phoretic particle interactions. Finally, the relevant physical approaches to quantify the emergent collective behavior are presented.

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Section: Motion In External Fluid Flowmentioning

confidence: 99%

Emergent behavior in active colloids

Zöttl

Stark

2016

J. Phys.: Condens. Matter

500

559

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“…Numerical and experimental works have revealed how gyrotactic motility, combined with the presence of a flow, generates strongly inhomogeneous distributions. In the case of laminar flow, gyrotaxis produces a beamlike accumulation in downwelling pipe flows [11], while in horizontal shear flow it generates accumulation in thin layers [10,15,16]. Recent works have shown that gyrotaxis also produces clustering at very small scales (comparable with the Kolmogorov scale) in nonstationary turbulent flows [17][18][19][20].…”

Section: Introductionmentioning

confidence: 99%

Scale-dependent colocalization in a population of gyrotactic swimmers

2017

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We study the small scale clustering of gyrotactic swimmers transported by a turbulent flow, when the intrinsic variability of the swimming parameters within the population is considered. By means of extensive numerical simulations, we find that the variety of the population introduces a characteristic scale R * in its spatial distribution. At scales smaller than R * the swimmers are homogeneously distributed, while at larger scales an inhomogeneous distribution is observed with a fractal dimension close to what observed for a monodisperse population characterized by mean parameters. The scale R * depends on the dispersion of the population and it is found to scale linearly with the standard deviation both for a bimodal and for a Gaussian distribution. Our numerical results, which extend recent findings for a monodisperse population, indicate that in principle it is possible to observe small scale, fractal clustering in a laboratory experiment with gyrotactic cells.

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“…In particular, an interesting feature to understand is how the coupling between flow and motility occurs [5,6]. This question has been addressed for instance in the case of gyrotactic algae in a flow [7,8]. Because of the eccentric location of their chloroplast, these algae are subject to a torque induced by gravity and consequently tend to swim upward.…”

mentioning

confidence: 99%

“…Because of the eccentric location of their chloroplast, these algae are subject to a torque induced by gravity and consequently tend to swim upward. Gyrotactic algae have been shown to concentrate in downwelling regions of turbulent flows [8]; this is a direct consequence of the migration of gyrotactic algae towards low vorticity regions as shown by Kessler [7].…”

mentioning

confidence: 99%

Photofocusing: Light and flow of phototactic microswimmer suspension

et al. 2016

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We explore in this paper the phenomenon of photofocusing: a coupling between flow vorticity and biased swimming of microalgae toward a light source that produces a focusing of the microswimmer suspension. We combine experiments that investigate the stationary state of this phenomenon as well as the transition regime with analytical and numerical modeling. We show that the experimentally observed scalings on the width of the focalized region and the establishment length as a function of the flow velocity are well described by a simple theoretical model.

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Gyrotactic trapping in laminar and turbulent Kolmogorov flow

Cited by 42 publications

References 46 publications

Emergent behavior in active colloids

Emergent behavior in active colloids

Scale-dependent colocalization in a population of gyrotactic swimmers

Photofocusing: Light and flow of phototactic microswimmer suspension

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