Please use this identifier to cite or link to this item: https://libjncir.jncasr.ac.in/xmlui/handle/10572/2438
Title: Stochastic dynamics of active swimmers in linear flows
Authors: Sandoval, Mario
Marath, Navaneeth K.
Subramanian, Ganesh
Lauga, Eric
Keywords: Mechanics
Fluids & Plasmas Physics
Biological Fluid Dynamics
Shear Flows
Low-Reynolds Number Locomotion
Homogeneous Shear Flows
Brownian Particles
Tumble Chemotaxis
Taylor Dispersion
Microorganisms
Diffusion
Run
Suspensions
Locomotion
Transport
Issue Date: 2014
Publisher: Cambridge Univ Press
Citation: Sandoval, M; Marath, NK; Subramanian, G; Lauga, E, Stochastic dynamics of active swimmers in linear flows. Journal of Fluid Mechanics 2014, 742, 50-70, http://dx.doi.org/10.1017/jfm.2013.651
Journal of Fluid Mechanics
742
Abstract: Most classical work on the hydrodynamics of low-Reynolds-number swimming addresses deterministic locomotion in quiescent environments. Thermal fluctuations in fluids are known to lead to a Brownian loss of the swimming direction, resulting in a transition from short-time ballistic dynamics to effective long-time diffusion. As most cells or synthetic swimmers are immersed in external flows, we consider theoretically in this paper the stochastic dynamics of a model active particle (a self-propelled sphere) in a steady general linear flow. The stochasticity arises both from translational diffusion in physical space, and from a combination of rotary diffusion and so-called run-and-tumble dynamics in orientation space. The latter process characterizes the manner in which the orientation of many bacteria decorrelates during their swimming motion. In contrast to rotary diffusion, the decorrelation occurs by means of large and impulsive jumps in orientation (tumbles) governed by a Poisson process. We begin by deriving a general formulation for all components of the long-time mean square displacement tensor for a swimmer with a time-dependent swimming velocity and whose orientation decorrelates due to rotary diffusion alone. This general framework is applied to obtain the convectively enhanced mean-squared displacements of a steadily swimming particle in three canonical linear flows (extension, simple shear and solid-body rotation). We then show how to extend our results to the case where the swimmer orientation also decorrelates on account of run-and-tumble dynamics Self-propulsion in general leads to the same long-time temporal scalings as for passive particles in linear flows but with increased coefficients. In the particular case of solid-body rotation, the effective long-time diffusion is the same as that in a quiescent fluid, and we clarify the lack of flow dependence by briefly examining the dynamics in elliptic linear flows. By comparing the new active terms with those obtained for passive particles we see that swimming can lead to an enhancement of the mean-square displacements by orders of magnitude, and could be relevant for biological organisms or synthetic swimming devices in fluctuating environmental or biological flows.
Description: Restricted Access
URI: https://libjncir.jncasr.ac.in/xmlui/10572/2438
ISSN: 0022-1120
Appears in Collections:Research Articles (Ganesh Subramanian)

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