Self-diffusion in dense granular shear flows

Utter, Brian; Behringer, Robert

doi:10.1103/physreve.69.031308

Cited by 179 publications

(215 citation statements)

References 36 publications

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“…The grains are compactified by the application of an external pressure of a specific value (typically 386 Pa), introduced by a moving piston at the top of the granular matrix. We use a narrow gap Couette cell of the order of seven particle diameters wide to avoid the formation of bulk shear bands (27)(28)(29)(30)(31).…”

Section: Methodsmentioning

confidence: 99%

Experimental measurement of an effective temperature for jammed granular materials

Wang

Makse

2005

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

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A densely packed granular system is an example of an out-ofequilibrium system in the jammed state. It has been a longstanding problem to determine whether this class of systems can be described by concepts arising from equilibrium statistical mechanics, such as an effective temperature and compactivity. The measurement of the effective temperature is realized in the laboratory by slowly shearing a closely packed ensemble of spherical beads confined by an external pressure in a Couette geometry. All of the probe particles considered in this study, independent of their characteristic features, equilibrate at the same temperature, given by the packing density of the system. granular matter ͉ jamming ͉ statistical mechanics of grains

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Section: Methodsmentioning

confidence: 99%

Experimental measurement of an effective temperature for jammed granular materials

Wang

Makse

2005

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

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“…Even in modern experiments, there is much that can be learned from comparing the spatial patterns of the force chains. For example, images of the force chains can reveal history dependence via spatial correlations [34,35], the ensemble-averaged response to point forces [36], and the principal axis of the response [37]. By subtracting images taken before/after an event, it is possible to examine spatial patterns of failure [19,38] and the speed of sound [24].…”

Section: Semi-quantitative Measurementsmentioning

confidence: 99%

Photoelastic force measurements in granular materials

Daniels

Kollmer

Puckett

2017

Review of Scientific Instruments

158

172

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Photoelastic techniques are used to make both qualitative and quantitative measurements of the forces within idealized granular materials. The method is based on placing a birefringent granular material between a pair of polarizing filters, so that each region of the material rotates the polarization of light according to the amount of local of stress. In this review paper, we summarize past work using the technique, describe the optics underlying the technique, and illustrate how it can be used to quantitatively determine the vector contact forces between particles in a 2D granular system. We provide a description of software resources available to perform this task, as well as key techniques and resources for building an experimental apparatus.

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“…Although diffusion can be anisotropic (Utter & Behringer 2004), for simplicity here we assume that D is isotropic. This approach has yielded results that qualitatively reproduce data from experiment and simulation in a variety of flows including plug (Gray & Chugunov 2006), chute (Marks et al 2011;Wiederseiner et al 2011;Thornton et al 2012), and an- Granular material is fed onto the heap at a volumetric feed rate Q, and the heap rises with velocity vr = Q/T W , where T is the gap thickness between the front and back walls.…”

Section: Introductionmentioning

confidence: 99%

Modelling size segregation of granular materials: the roles of segregation, advection and diffusion

et al. 2014

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Predicting segregation of granular materials composed of different-sized particles is a challenging problem. In this paper, we develop and implement a theoretical model that captures the interplay between advection, segregation, and diffusion in size bidisperse granular materials. The fluxes associated with these three driving factors depend on the underlying kinematics, whose characteristics play key roles in determining particle segregation configurations. Unlike previous models for segregation, our model uses parameters based on kinematic measures from discrete element method simulations instead of arbitrarily adjustable fitting parameters, and it achieves excellent quantitative agreement with both experimental and simulation results when applied to quasi-two-dimensional bounded heaps. The model yields two dimensionless control parameters, both of which are only functions of physically control parameters (feed rate, particle sizes, and system size) and kinematic parameters (diffusion coefficient, flowing layer depth, and percolation velocity). The Péclet number, P e, captures the interplay of advection and diffusion, and the second dimensionless parameter, Λ, describes the interplay between segregation and advection. A parametric study of Λ and P e demonstrates how the particle segregation configuration depends on the interplay of advection, segregation, and diffusion. The model can be readily adapted to other flow geometries.Key words: Authors should not enter keywords on the manuscript, as these must be chosen by the author during the online submission process and will then be added during the typesetting process (see http://journals.cambridge.org/data/relatedlink/jfm-keywords.pdf for the full list) †

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Self-diffusion in dense granular shear flows

Cited by 179 publications

References 36 publications

Experimental measurement of an effective temperature for jammed granular materials

Experimental measurement of an effective temperature for jammed granular materials

Photoelastic force measurements in granular materials

Modelling size segregation of granular materials: the roles of segregation, advection and diffusion

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