Effect of fluid inertia on the dynamics and scaling of neutrally buoyant particles in shear flow

Rosén, Tomas; Lundell, Fredrik; Aidun, Cyrus K.

doi:10.1017/jfm.2013.599

Cited by 61 publications

(87 citation statements)

References 28 publications

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“…This explains why stable log-rolling is not observed in DNS [3][4][5][6] at the smallest shear Reynolds numbers accessible in the simulations. Moreover, we find that tumbling in the flow-shear plane is stable for prolate particles.…”

Section: Introductionmentioning

confidence: 88%

“…The question is currently of great interest: several recent papers have reported results of direct numerical simulations (DNSs) of the problem, using "lattice Boltzmann" methods. [3][4][5][6] These studies reveal that fluid and particle inertias affect the orientational dynamics of a neutrally buoyant spheroid in a simple shear in intricate ways. The DNSs are performed at moderate and large shear Reynolds numbers, defined as Re s = sa 2 /ν, where a is the largest particle dimension, s is the shear strength, and ν the kinematic viscosity of the suspending fluid.…”

Section: Introductionmentioning

confidence: 93%

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Rotation of a spheroid in a simple shear at small Reynolds number

et al. 2015

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We derive an effective equation of motion for the orientational dynamics of a neutrally buoyant spheroid suspended in a simple shear flow, valid for arbitrary particle aspect ratios and to linear order in the shear Reynolds number. We show how inertial effects lift the degeneracy of the Jeffery orbits and determine the stabilities of the log-rolling and tumbling orbits at infinitesimal shear Reynolds numbers. For prolate spheroids we find stable tumbling in the shear plane, log-rolling is unstable. For oblate particles, by contrast, log-rolling is stable and tumbling is unstable provided that the aspect ratio is larger than a critical value. When the aspect ratio is smaller than this value tumbling turns stable, and an unstable limit cycle is born.

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Section: Introductionmentioning

confidence: 88%

Section: Introductionmentioning

confidence: 93%

Rotation of a spheroid in a simple shear at small Reynolds number

et al. 2015

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“…Leal (1980) provides a review of the older literature, and a wide range of work has followed, for example: Koch & Shaqfeh (1989); Szeri & Leal (1993); Herzhaft et al (1996); Olson & Kerekes (1998); Parsa et al (2011); Rosen et al (2014); Andersson & Soldati (2013). Turbulent flows advecting anisotropic particles provide a compelling test case, both because of the many applications and because of the nearly universal statistics of the velocity gradients experienced by small particles in many turbulent flows at large Reynolds number.…”

Section: Introductionmentioning

confidence: 99%

Measurements of the coupling between the tumbling of rods and the velocity gradient tensor in turbulence

Kramel

Ouellette

et al. 2015

J. Fluid Mech.

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We present simultaneous experimental measurements of the dynamics of anisotropic particles transported by a turbulent flow and the velocity gradient tensor of the flow surrounding them. We track both rod-shaped particles and small spherical flow tracers using stereoscopic particle tracking. By using scanned illumination, we are able to obtain a high enough seeding density of tracers to measure the full velocity gradient tensor near the rod. The alignment of rods with the vorticity and the eigenvectors of the strain rate show agreement with numerical simulations. A full description of the tumbling of rods in turbulence requires specifying a seven-dimensional joint probability density function (PDF) of five scalars characterizing the velocity gradient tensor and two scalars describing the relative orientation of the rod. If these seven parameters are known, then Jeffery's equation specifies the rod tumbling rate and any statistic of rod rotations can be obtained as a weighted average over the joint PDF. To look for a lower-dimensional projection to simplify the problem, we explore conditional averages of the mean-squared tumbling rate. The conditional dependence of the mean-squared tumbling rate on the magnitude of both the vorticity and the strain rate is strong, as expected, and similar. There is also a strong dependence on the orientation between the rod and the vorticity, since a rod aligned with the vorticity vector tumbles due to strain but not vorticity. When conditioned on the alignment of the rod with the eigenvectors of the strain rate, the largest tumbling rate is obtained when the rod is oriented at a certain angle to the eigenvector that corresponds to the smallest eigenvalue, because this particular orientation maximizes the contribution from both the vorticity and strain.

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“…The effect of inertia on path selection of a capsule at a bifurcation remains unknown. In other systems, for example non-spherical particles in shear flows, it has been shown that inertial effect could fundamentally change the dynamics of particles even at low Reynolds number (Rosén, Lundell & Aidun 2014;Dabade, Marath & Subramanian 2016). Furthermore, when a capsule approaches the bifurcation, it can sustain high shear stresses, which may damage the capsule membrane.…”

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confidence: 99%

Motion of a spherical capsule in branched tube flow with finite inertia

et al. 2016

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We computationally study the transient motion of an initially spherical capsule flowing through a right-angled tube bifurcation, composed of tubes having the same diameter. The capsule motion and deformation is simulated using a three-dimensional immersed-boundary lattice Boltzmann method. The capsule is modelled as a liquid droplet enclosed by a hyperelastic membrane following the Skalak's law (Skalak et al., Biophys. J., vol. 13(3), 1973, pp. 245-264). The fluids inside and outside the capsule are assumed to have identical viscosity and density. We mainly focus on path selection of the capsule at the bifurcation as a function of the parameters of the problem: the flow split ratio, the background flow Reynolds number Re, the capsule-to-tube size ratio a/R and the capillary number Ca, which compares the viscous fluid force acting on the capsule to the membrane elastic force. For fixed physical properties of the capsule and of the tube flow, the ratio Ca/Re is constant. Two size ratios are considered: a/R = 0.2 and 0.4. At low Re, the capsule favours the branch which receives most flow. Inertia significantly affects the background flow in the branched tube. As a consequence, at equal flow split, a capsule tends to flow straight into the main branch as Re is increased. Under significant inertial effects, the capsule can flow into the downstream main tube even when it receives much less flow than the side branch. Increasing Ca promotes cross-stream migration of the capsule towards the side branch. The results are summarized in a phase diagram, showing the critical flow split ratio for which the capsule flows into the side branch as a function of size ratio, Re and Ca/Re. We also provide a simplified model of the path selection of a slightly deformed capsule and explore its limits of validity. We finally discuss the experimental feasibility of the flow system and its applicability to capsule sorting.

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Effect of fluid inertia on the dynamics and scaling of neutrally buoyant particles in shear flow

Cited by 61 publications

References 28 publications

Rotation of a spheroid in a simple shear at small Reynolds number

Rotation of a spheroid in a simple shear at small Reynolds number

Measurements of the coupling between the tumbling of rods and the velocity gradient tensor in turbulence

Motion of a spherical capsule in branched tube flow with finite inertia

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