Dynamics of Flexible Fibers in Viscous Flows and Fluids

Roure, Olivia du; Lindner, Anke; Nazockdast, Ehssan; Shelley, Michael

doi:10.1146/annurev-fluid-122316-045153

Cited by 166 publications

(162 citation statements)

References 159 publications

(269 reference statements)

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“…For instance, the consideration of soft deformable sensors has already motivated extensive studies of attached filaments (Guglielmini et al 2012;Roper et al 2006), as has the characterisation of attached filament forces for understanding the drag induced by slender appendages (Curtis et al 2012;Pozrikidis 2011;Simons et al 2014). Such appendages range from the primary cilium to carbon nanotube mats, with an extensive review of the field presented by du Roure et al (2019), which notes that both theoretical and numerical developments are very much still required in this field. Indeed, with advances in microscopy enabling ever more detailed quantification of kinematics, often with confining geometry such as a cover slip or substrate, the development of validated, and ideally simple, methodologies would be beneficial in estimating mechanics from kinematics.…”

Section: Introductionmentioning

confidence: 99%

Filament mechanics in a half-space via regularised Stokeslet segments

et al. 2019

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We present a generalisation of efficient numerical frameworks for modelling fluid-filament interactions via the discretisation of a recently-developed, non-local integral equation formulation to incorporate regularised Stokeslets with half-space boundary conditions, as motivated by the importance of confining geometries in many applications. We proceed to utilise this framework to examine the drag on slender inextensible filaments moving near a boundary, firstly with a relatively-simple example, evaluating the accuracy of resistive force theories near boundaries using regularised Stokeslet segments. This highlights that resistive force theories do not accurately quantify filament dynamics in a range of circumstances, even with analytical corrections for the boundary. However, there is the notable and important exception of movement in a plane parallel to the boundary, where accuracy is maintained. In particular, this justifies the judicious use of resistive force theories in examining the mechanics of filaments and monoflagellate microswimmers with planar flagellar patterns moving parallel to boundaries. We proceed to apply the numerical framework developed here to consider how filament elastohydrodynamics can impact drag near a boundary, analysing in detail the complex responses of a passive cantilevered filament to an oscillatory flow. In particular, we document the emergence of an asymmetric periodic beating in passive filaments in particular parameter regimes, which are remarkably similar to the power and reverse strokes exhibited by motile 9+2 cilia. Furthermore, these changes in the morphology of the filament beating, arising from the fluid-structure interactions, also induce a significant increase in the hydrodynamic drag of the filament. †

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Section: Introductionmentioning

confidence: 99%

Filament mechanics in a half-space via regularised Stokeslet segments

et al. 2019

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“…Experimental and computational progress on flexible fibers in fluid flow has recently been reviewed by du Roure et al with an emphasis on microscopic systems. In one type of simulation approach fibers are represented by chains of connected spheres .…”

Section: Introductionmentioning

confidence: 99%

Suspension of flexible cylinders in laminar liquid flow

Derksen

2020

AIChE Journal

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A methodology for particle-resolved simulation of dense suspensions of flexible cylindrical particles in Newtonian liquid flow is described. It is based on the Lattice-Boltzmann method for solving the liquid flow and an immersed boundary method for imposing no-slip at the particle surfaces and providing the distribution of liquid-solid interaction forces over the particle surfaces. These forces-along with contact forcestranslate, rotate as well as bend the cylindrical particles. Verification tests have been performed for a single cylinder settling and deforming under gravity at a low Reynolds number. The method has been applied to a clamped flexible cylinder in microchannel flow for which experimental data are available. It then is used to investigate the behavior of hundreds of flexible cylinders with length over diameter aspect ratios of 4 and 6 in a container agitated by an impeller at a Reynolds number of 87 which implies laminar flow. The overall solids volume fraction is 15%. We study the effect of the bending stiffness of the particles on the solids suspension process, on the extent of particle deformation as well as on the torque required to spin the impeller. K E Y W O R D Sbending stiffness, flexible particles, Lattice-Boltzmann method, liquid-solids flow, particle-

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“…In low Reynolds number flows, although flows are stable, complexity arises from non-linear interactions between deformable structures and viscous flow. Viscous fluid motion can modify the shape, orientation and position of a structure which in turn leads to coupling between the flow field and the structural response 8 . FSI studies of these flows are relevant to the biological and physiological world seen in the flow past flagella 9 , swimming of micro-organisms 10 , the deformation of red blood cells during transport in blood vessels 11 or the deformation of soft fluid-conveying vessels 12,13 .…”

Section: Introductionmentioning

confidence: 99%

Oscillations of a cantilevered micro beam driven by a viscoelastic flow instability

et al. 2020

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The interaction of flexible structures with viscoelastic flows can result in very rich dynamics. In this paper, we present the results of the interactions between the flow of a viscoelastic polymer solution and a cantilevered beam in a confined microfluidic geometry. Cantilevered beams with varying length and flexibility were studied. With increasing flow rate and Weissenberg number, the flow transitioned from a fore-aft symmetric flow to a stable detached vortex upstream of the beam, to a time-dependent unstable vortex shedding. The shedding of the unstable vortex upstream of the beam imposed a time-dependent drag force on the cantilevered beam resulting in flow-induced beam oscillations. The oscillations of the flexible beam were classified into two distinct regimes: a regime with a clear single vortex shedding from upstream of the beam resulting in a sinusoidal beam oscillation pattern with the frequency of oscillation increasing monotonically with Weissenberg number, and a regime at high Weissenberg numbers characterized by 3D chaotic flow instabilities where the frequency of oscillations plateaued. The critical onset of the flow transitions, the mechanism of vortex shedding and the dynamics of the cantilevered beam response are presented in detail here as a function of beam flexibility and flow viscoelasticity.Alternatively, allowing these instabilities to affect the position, deformation and motion of an object falls in the domain of fluidstructure interaction problems and introduces a host of interesting questions regarding the dynamics and elasticity of the struc-J o u r n a l N a me , [ y e a r ] , [ v o l . ] , 1-8 | 1 arXiv:1910.04203v1 [physics.flu-dyn] 9 Oct 2019A second set of experiments was conducted where the flexible Beam 1 was replaced with a more flexible beam, Beam 2 (see details in Table 1) which had the same beam width and elastic modulus but a longer beam length while maintaining a similar chan-J o u r n a l N a me , [ y e a r ] , [ v o l . ] , 1-8 | 5

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Dynamics of Flexible Fibers in Viscous Flows and Fluids

Cited by 166 publications

References 159 publications

Filament mechanics in a half-space via regularised Stokeslet segments

Filament mechanics in a half-space via regularised Stokeslet segments

Suspension of flexible cylinders in laminar liquid flow

Oscillations of a cantilevered micro beam driven by a viscoelastic flow instability

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