Stirring by periodic arrays of microswimmers

Joost De Graaf; Joakim Stenhammar

doi:10.1017/jfm.2016.797

Stirring by periodic arrays of microswimmers

Joost De Graaf^*
, Joakim Stenhammar

^*Corresponding author for this work

Theoretical Physics

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

The interaction between swimming micro-organisms or artificial self-propelled colloids and passive (tracer) particles in a fluid leads to enhanced diffusion of the tracers. This enhancement has attracted strong interest, as it could lead to new strategies to tackle the difficult problem of mixing on a microfluidic scale. Most of the theoretical work on this topic has focused on hydrodynamic interactions between the tracers and swimmers in a bulk fluid. However, in simulations, periodic boundary conditions (PBCs) are often imposed on the sample and the fluid. Here, we theoretically analyse the effect of PBCs on the hydrodynamic interactions between tracer particles and microswimmers. We formulate an Ewald sum for the leading-order stresslet singularity produced by a swimmer to probe the effect of PBCs on tracer trajectories. We find that introducing periodicity into the system has a surprisingly significant effect, even for relatively small swimmer-tracer separations. We also find that the bulk limit is only reached for very large system sizes, which are challenging to simulate with most hydrodynamic solvers.

Original language	English
Pages (from-to)	487-498
Number of pages	12
Journal	Journal of Fluid Mechanics
Volume	811
DOIs	https://doi.org/10.1017/jfm.2016.797
Publication status	Published - 25 Jan 2017

Bibliographical note

Funding Information:
Helpful discussions with M. Cates, L. af Klinteberg, A. Morozov and C. Nardini are kindly acknowledged. J.d.G. thanks the 'Deutsche Forschungsgemeinschaft' (DFG) for funding through the SPP 1726 'Microswimmers: from single particle motion to collective behavior' and gratefully acknowledges funding by a Marie Sk?odowska-Curie Intra European Fellowship (G.A. no. 654916) within Horizon 2020. J.S. is financed by a Project Grant from the Swedish Research Council (2015-05449).

Publisher Copyright:
© 2016 Cambridge University Press.

Funding

Helpful discussions with M. Cates, L. af Klinteberg, A. Morozov and C. Nardini are kindly acknowledged. J.d.G. thanks the 'Deutsche Forschungsgemeinschaft' (DFG) for funding through the SPP 1726 'Microswimmers: from single particle motion to collective behavior' and gratefully acknowledges funding by a Marie Sk?odowska-Curie Intra European Fellowship (G.A. no. 654916) within Horizon 2020. J.S. is financed by a Project Grant from the Swedish Research Council (2015-05449).

Keywords

computational methods
micro-organism dynamics
Navier-Stokes equations

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10.1017/jfm.2016.797

Cite this

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title = "Stirring by periodic arrays of microswimmers",

abstract = "The interaction between swimming micro-organisms or artificial self-propelled colloids and passive (tracer) particles in a fluid leads to enhanced diffusion of the tracers. This enhancement has attracted strong interest, as it could lead to new strategies to tackle the difficult problem of mixing on a microfluidic scale. Most of the theoretical work on this topic has focused on hydrodynamic interactions between the tracers and swimmers in a bulk fluid. However, in simulations, periodic boundary conditions (PBCs) are often imposed on the sample and the fluid. Here, we theoretically analyse the effect of PBCs on the hydrodynamic interactions between tracer particles and microswimmers. We formulate an Ewald sum for the leading-order stresslet singularity produced by a swimmer to probe the effect of PBCs on tracer trajectories. We find that introducing periodicity into the system has a surprisingly significant effect, even for relatively small swimmer-tracer separations. We also find that the bulk limit is only reached for very large system sizes, which are challenging to simulate with most hydrodynamic solvers.",

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N2 - The interaction between swimming micro-organisms or artificial self-propelled colloids and passive (tracer) particles in a fluid leads to enhanced diffusion of the tracers. This enhancement has attracted strong interest, as it could lead to new strategies to tackle the difficult problem of mixing on a microfluidic scale. Most of the theoretical work on this topic has focused on hydrodynamic interactions between the tracers and swimmers in a bulk fluid. However, in simulations, periodic boundary conditions (PBCs) are often imposed on the sample and the fluid. Here, we theoretically analyse the effect of PBCs on the hydrodynamic interactions between tracer particles and microswimmers. We formulate an Ewald sum for the leading-order stresslet singularity produced by a swimmer to probe the effect of PBCs on tracer trajectories. We find that introducing periodicity into the system has a surprisingly significant effect, even for relatively small swimmer-tracer separations. We also find that the bulk limit is only reached for very large system sizes, which are challenging to simulate with most hydrodynamic solvers.

AB - The interaction between swimming micro-organisms or artificial self-propelled colloids and passive (tracer) particles in a fluid leads to enhanced diffusion of the tracers. This enhancement has attracted strong interest, as it could lead to new strategies to tackle the difficult problem of mixing on a microfluidic scale. Most of the theoretical work on this topic has focused on hydrodynamic interactions between the tracers and swimmers in a bulk fluid. However, in simulations, periodic boundary conditions (PBCs) are often imposed on the sample and the fluid. Here, we theoretically analyse the effect of PBCs on the hydrodynamic interactions between tracer particles and microswimmers. We formulate an Ewald sum for the leading-order stresslet singularity produced by a swimmer to probe the effect of PBCs on tracer trajectories. We find that introducing periodicity into the system has a surprisingly significant effect, even for relatively small swimmer-tracer separations. We also find that the bulk limit is only reached for very large system sizes, which are challenging to simulate with most hydrodynamic solvers.

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ER -

Stirring by periodic arrays of microswimmers

Abstract

Bibliographical note

Funding

Keywords

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