Please use this identifier to cite or link to this item: https://libjncir.jncasr.ac.in/xmlui/handle/10572/1965
Title: Collective motion in a suspension of micro-swimmers that run-and-tumble and rotary diffuse
Authors: Krishnamurthy, Deepak
Subramanian, Ganesh
Keywords: Mechanics
Fluids & Plasmas Physics
biological fluid dynamics
instability
micro-organism dynamics
Swimming Model Microorganisms
Bacillus-Subtilis
Coherent Structures
Bacterial Dynamics
Stokesian Dynamics
Particle Tracking
Escherichia-Coli
Simulations
Sedimentation
Flow
Issue Date: 2015
Publisher: Cambridge University Press
Citation: Journal of Fluid Mechanics
781
Krishnamurthy, D.; Subramanian, G., Collective motion in a suspension of micro-swimmers that run-and-tumble and rotary diffuse. Journal of Fluid Mechanics 2015, 781, 422-466.
Abstract: Recent experiments have shown that suspensions of swimming micro-organisms are characterized by complex dynamics involving enhanced swimming speeds, large-scale correlated motions and enhanced diffusivities of embedded tracer particles. Understanding this dynamics is of fundamental interest and also has relevance to biological systems. The observed collective dynamics has been interpreted as the onset of a hydrodynamic instability, of the quiescent isotropic state of pushers, swimmers with extensile force dipoles, above a critical threshold proportional to the swimmer concentration. In this work, we develop a particle-based model to simulate a suspension of hydrodynamically interacting rod-like swimmers to estimate this threshold. Unlike earlier simulations, the velocity disturbance field due to each swimmer is specified in terms of the intrinsic swimmer stress alone, as per viscous slender-body theory. This allows for a computationally efficient kinematic simulation where the interaction law between swimmers is known a priori. The neglect of induced stresses is of secondary importance since the aforementioned instability arises solely due to the intrinsic swimmer force dipoles. Our kinematic simulations include, for the first time, intrinsic decorrelation mechanisms found in bacteria, such as tumbling and rotary diffusion. To begin with, we simulate so-called straight swimmers that lack intrinsic orientation decorrelation mechanisms, and a comparison with earlier results serves as a proof of principle. Next, we simulate suspensions of swimmers that tumble and undergo rotary diffusion, as a function of the swimmer number density (n), and the intrinsic decorrelation time (the average duration between tumbles, tau, for tumblers, and the inverse of the rotary diffusivity, D-r(-1), for rotary diffusers). The simulations, as a function of the decorrelation time, are carried out with hydrodynamic interactions (between swimmers) turned off and on, and for both pushers and pullers (swimmers with contractile force dipoles). The 'interactions-off' simulations allow for a validation based on analytical expressions for the tracer diffusivity in the stable regime, and reveal a non-trivial box size dependence that arises with varying strength of the hydrodynamic interactions. The 'interactions-on' simulations lead us to our main finding: the existence of a box-size-independent parameter that characterizes the onset of instability in a pusher suspension, and is given by nUL(2)tau for tumblers and nUL(2)/D-r for rotary diffusers; here, U and L are the swimming speed and swimmer length, respectively. The instability manifests as a bifurcation of the tracer diffusivity curves, in pusher and puller suspensions, for values of the above dimensionless parameters exceeding a critical threshold.
Description: Restricted access
URI: https://libjncir.jncasr.ac.in/xmlui/10572/1965
ISSN: 0022-1120
Appears in Collections:Research Articles (Ganesh Subramanian)

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