2015
DOI: 10.1063/1.4913851
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Rarefaction-singular shock dynamics for conserved volume gravity driven particle-laden thin film

Abstract: We employ a recently proposed model [Murisic et al., “Dynamics of particle settling and resuspension in viscous liquids,” J. Fluid. Mech. 717, 203–231 (2013)] to study a finite-volume, particle-laden thin film flowing under gravity on an incline. For negatively buoyant particles with concentration above a critical value and buoyant particles, the particles accumulate at the front of the flow forming a particle-rich ridge, whose similarity solution is of the rarefaction-singular shock type. We investigate the s… Show more

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Cited by 7 publications
(15 citation statements)
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“…In section 5 we derive theoretical results for the long-time behavior of monodisperse suspensions in the settled regime, where the concentration of particles uniformly approaches a critical concentration independent of initial conditions. The asymptotic behavior of the front positions is derived, extending the existing results for the high-concentration [19,20] and dilute limit [12]. The results are then extended qualitatively to the bidisperse problem.…”
Section: Introductionmentioning
confidence: 69%
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“…In section 5 we derive theoretical results for the long-time behavior of monodisperse suspensions in the settled regime, where the concentration of particles uniformly approaches a critical concentration independent of initial conditions. The asymptotic behavior of the front positions is derived, extending the existing results for the high-concentration [19,20] and dilute limit [12]. The results are then extended qualitatively to the bidisperse problem.…”
Section: Introductionmentioning
confidence: 69%
“…The theory for the dilute limit of the dynamic model was studied in [12], where an exact solution for the rarefaction can be found, and the particle front was shown to evolve as x p = (C p t) 1/3 + T 0 + O(t −1/3 ) for some constant T 0 . A similar behavior occurs in the high-concentration limit, where one obtains a rarefaction and a singular shock [19] and the exponent α in x f (t) ∼ t α is perturbed slightly from 1/3 due to the accumulation of mass at the front.…”
Section: Long-term Behavior: Monodispersementioning
confidence: 81%
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