Particle velocity fluctuations and correlation lengths in dilute sedimenting suspensions

Bernard-Michel, Gilles; Monavon, A.; Lhuillier, Daniel; Abdo, D.; Simon, H.

doi:10.1063/1.1483302

Cited by 30 publications

(31 citation statements)

References 16 publications

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“…We performed some simulations with a container where L y L z which seem to suggest that in such cases the correlation lengths of R yy ͑r͒ and R yz ͑r͒ are defined by the smaller of these dimensions, which is again in a good agreement with the results in Ref. [35]. The correlation lengths of R zx ͑r͒ and R zy ͑r͒ seem to depend both on L x and L periodic even when the former is much smaller than the latter.…”

Section: Velocity Fluctuationssupporting

confidence: 86%

“…The shapes of R xx ͑r͒ and R xz ͑r͒ are quite similar to the corresponding SVC's shown in Ref. [35]. For the y component of the particle velocities all correlation lengths increase seemingly linearly with increasing L periodic .…”

Section: Velocity Fluctuationssupporting

confidence: 80%

“…This time simulations performed with L y L z indicate that the correlation lengths depend on L y even if L y Ͻ L z leading again to a scaling similar to that in Ref. [35]. The scaling of R zz ͑r͒, however, differs significantly from the previous by the fact that the correlation length depends also on ⌽.…”

Section: Velocity Fluctuationssupporting

confidence: 68%

“…A further reason not to expect similar scaling in the present simulations is that the saturation has been shown to be a result of having walls in the direction of gravity. However, the experiments of Bernard-Michel et al [35], performed in a long tube with smaller square cross section (width less or equal than 800a) show almost linear relation between the correlation length of the SVC and the width of the container with no ⌽ dependence. In all directions our measured R x␤ ͑r͒ depends only on L x provided that L x Ͻ L periodic .…”

Section: Velocity Fluctuationsmentioning

confidence: 90%

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Sedimentation dynamics of spherical particles in confined geometries

2004

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We study the steady-state dynamics of sedimenting non-Brownian particles in confined geometries with full hydrodynamic interactions at small but finite Reynolds numbers. We employ extensive computer simulations using a method where a continuum liquid phase is coupled through Stokesian friction to a discrete particle phase. In particular, we consider a sedimentation box which is otherwise periodic except that it is confined by two parallel walls parallel to gravity with a spacing L x . By systematically varying L x we explore the change in dynamics from a quasi-two-dimensional (2D) case to a three-dimensional case. We find that in such confined geometries there is a depletion of particle number density at the walls for small volume fractions, while for large volume fractions there is an excess number of particles at the walls. For the average sedimentation velocity, we find that the Richardson-Zaki law is well obeyed but the decrease of the velocity for dilute systems is slower for smaller values of L x . We study the anisotropy of the velocity fluctuations and find that in the direction of gravity there is excellent agreement with the predicted scaling with respect to L x . We also find that the behavior of the corresponding diffusion coefficients as a function of L x is qualitatively different in the direction parallel to gravity and perpendicular to it. In the quasi-2D limit where particles block each other, the velocity fluctuations behave differently from the other confined systems.

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Section: Velocity Fluctuationssupporting

confidence: 86%

Section: Velocity Fluctuationssupporting

confidence: 80%

Section: Velocity Fluctuationssupporting

confidence: 68%

Section: Velocity Fluctuationsmentioning

confidence: 90%

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Sedimentation dynamics of spherical particles in confined geometries

2004

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“…The mean sedimentation velocity of a suspension can be predicted theoretically at low particle volume fraction 1 and by using sophisticated computer simulations at larger volume fractions, but the individual movement of particles due to long-range hydrodynamic interactions gives rise to velocity fluctuations that are still not completely understood. [2][3][4][5][6][7][8][9][10][11][12][13] Lately, the study of the spreading of the sedimentation front has regained interest 12,13 as it has been advocated that a small vertical stratification due to the broadening of this front can change the characteristics of the velocity fluctuations. [10][11][12] One can find a few experimental investigations of the spreading of this front in the literature showing the importance of different effects, such as hydrodynamic dispersion, polydispersity of the particles, and hindered settling.…”

Section: Introductionmentioning

confidence: 99%

Spreading fronts in sedimentation of dilute suspension of spheres

Gomez¹,

Bergougnoux²,

Guazzelli³

et al. 2008

Physics of Fluids

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The thickness of the diffuse front between a sedimenting dilute suspension and the clear fluid above grows linearly in time due to polydispersity in the size of the particles and due to a hydrodynamic effect in which randomly heavy clusters fall out of the front leaving it depleted. Experiments and simplified point-particle numerical simulations agree that these two effects are not simply linearly additive.

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A simple apparatus for measuring cell settling velocity

Wang

Belovich

2010

Biotechnology Progress

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Accurate cell settling velocity determination is critical for perfusion culture using a gravity settler for cell retention. We have developed a simple apparatus (a “settling column”) for measuring settling velocity and have validated the procedure with 15‐μm polystyrene particles with known physical properties. The measured settling velocity of the polystyrene particles is within 4% of the value obtained using the traditional Stokes' law approach. The settling velocities of three hybridoma cell lines were measured, resulting in up to twofold variation among cell lines, and the values decreased as the cell culture aged. The settling velocities of the nonviable cells were 33–50% less than the corresponding viable cells. The significant variation of settling velocities among cell populations and growth phases confirms the necessity of routine measurement of this property during long‐term perfusion culture. © 2010 American Institute of Chemical Engineers Biotechnol. Prog., 2010

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Particle velocity fluctuations and correlation lengths in dilute sedimenting suspensions

Cited by 30 publications

References 16 publications

Sedimentation dynamics of spherical particles in confined geometries

Sedimentation dynamics of spherical particles in confined geometries

Spreading fronts in sedimentation of dilute suspension of spheres

A simple apparatus for measuring cell settling velocity

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