Complexity, segregation, and pattern formation in rotating-drum flows

Seiden, Gabriel; Thomas, Peter J.

doi:10.1103/revmodphys.83.1323

Cited by 141 publications

(111 citation statements)

References 225 publications

(545 reference statements)

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“…Particles below it (the fixed bed) are in static equilibrium and perform solid body rotation in unison with the container (41)(42)(43). This flow rapidly reaches steady state (10,42), at which point, to a good approximation, the volume fractions and macroscopic (averaged) densities of the material in the flowing layer and the bulk are constant and equal. For a monodisperse granular material, all particles are identical, and c is the concentration of the tagged particles (e.g., black in color), while 1 − c is the concentration of the nontagged particles (e.g., white in color).…”

Section: Modelmentioning

confidence: 99%

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Resolving a paradox of anomalous scalings in the diffusion of granular materials

Christov

Stone

2012

Proc. Natl. Acad. Sci. U.S.A.

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Granular materials do not perform Brownian motion, yet diffusion can be observed in such systems when agitation causes inelastic collisions between particles. It has been suggested that axial diffusion of granular matter in a rotating drum might be “anomalous” in the sense that the mean squared displacement of particles follows a power law in time with exponent less than unity. Further numerical and experimental studies have been unable to definitively confirm or disprove this observation. We show two possible resolutions to this apparent paradox without the need to appeal to anomalous diffusion. First, we consider the evolution of arbitrary (non-point-source) initial data towards the self-similar intermediate asymptotics of diffusion by deriving an analytical expression for the instantaneous collapse exponent of the macroscopic concentration profiles. Second, we account for the concentration-dependent diffusivity in bidisperse mixtures, and we give an asymptotic argument for the self-similar behavior of such a diffusion process, for which an exact self-similar analytical solution does not exist. The theoretical arguments are verified through numerical simulations of the governing partial differential equations, showing that concentration-dependent diffusivity leads to two intermediate asymptotic regimes: one with an anomalous scaling that matches the experimental observations for naturally polydisperse granular materials, and another with a “normal” diffusive scaling (consistent with a “normal” random walk) at even longer times.

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Section: Modelmentioning

confidence: 99%

“…In particular, granular flow in a long rotating horizontal drum has proven to be a simple but important system to understand (10). Recently, it has been suggested that axial diffusion in this system is anomalous (11).…”

mentioning

confidence: 99%

Resolving a paradox of anomalous scalings in the diffusion of granular materials

Christov

Stone

2012

Proc. Natl. Acad. Sci. U.S.A.

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“…Granular materials and powders in rotating drums are of wide interest not only because of their extensive use in the chemical, minerals, pharmacutical and food processing contexts, but also as model systems in the study of natural disasters, such as avalanches or landslides (Meier et al, 2007;Seiden and Thomas, 2011).…”

Section: Inroductionmentioning

confidence: 99%

Granular dynamics of cohesive powders in a rotating drum as revealed by speckle visibility spectroscopy and synchronous measurement of forces due to avalanching

Yang

Jiang

Saw

et al. 2016

Chemical Engineering Science

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We have used speckle visibility spectroscopy (SVS) and synchronized force measurements to compare the granular dynamics of two cohesive lactose powders, with Sauter mean diameters of ~29 μm and ~151 μm, in a rotating drum. A load cell (LC) was used to measure forces on the drum mounting frame and enable monitoring of bulk powder motion; SVS is a dynamic light scattering technique particularly suited for studying dynamics in dense, non-ergodic granular systems. Our results reveal that surface slumping and intermittent collisional dynamics in the bulk of the bed are correlated, especially for the fine more cohesive particles (Geldart group C/A boundary), but not as much for the less cohesive larger particles (Geldart group A/B boundary). The specific dissipation energy of the particles in the drum is similar for both powders, and increases linearly with increasing drum speed. However, the dependencies of the load cell and SVS signals on rotation speed have opposing trends for these two powders, indicating different dissipation mechanisms for the different Geldart Groups; collisional dissipation is more important for the Geldart C/A powder, while for the Geldart A/B powder avalanche dissipation is dominant.

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“…That is what makes granular science very exciting. If a bidisperse mixture of differently sized grains is rotated horizontally in a cylindrical drum, a complex scenario of segregation processes is found [2]. Radial segregation takes place in the first ≈5 rotations, followed by axial segregation after ≈100 rotations.…”

Section: Introductionmentioning

confidence: 99%

Segregation and convection rolls in two-dimensional packings

Rietz¹

2013

AIP Conference Proceedings

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Abstract. Self-organized pattern formation in two-dimensional packings is reported. Continuous rotation of a densely packed monolayer leads to two possible states: either the packing segregates without any recognizable collective particle motion, or the packing stays mixed and the particles move in regular convection rolls. The reason for the different observations is so far not known. Irrespective of the simplicity of the experiment, the driving mechanism must be completely different from other pattern forming systems in granular media.

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Complexity, segregation, and pattern formation in rotating-drum flows

Cited by 141 publications

References 225 publications

Resolving a paradox of anomalous scalings in the diffusion of granular materials

Resolving a paradox of anomalous scalings in the diffusion of granular materials

Granular dynamics of cohesive powders in a rotating drum as revealed by speckle visibility spectroscopy and synchronous measurement of forces due to avalanching

Segregation and convection rolls in two-dimensional packings

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