![[wedges]](http://pg.chem-eng.nwu.edu/mixing/papers/Nature/nature_fig1.gif)
Figure: 1 Schematic of avalanche
mixing. For slow rotation speed, W, distinct avalanches occur which take
material from an uphill wedge to a downhill wedge, as indicated by the solid
arrow. Mixing within the wedges is taken to obey a deterministic map; mixing
between wedges occurs in quadrilateral wedge intersections.
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![[disk comparisons]](http://pg.chem-eng.nwu.edu/mixing/papers/Nature/nature_fig2.gif)
Figure: 2 Mixing patterns from
simulation (left) and experiment (right) after two disk revolutions at the
indicated fill levels. To initialize an experiment, we lay a divider along the
disk diameter and pour equal amounts of red (blue) salt into the right (left)
side. We then remove the divider, seal the top, and set the disk on edge. For
low fill levels, note the similar interpenetration of colors across the disk and
the equivalent degree of mixedness. For high fill levels, an unmixed core
appears with reduced mixing rates outside the core.
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![[rates]](http://pg.chem-eng.nwu.edu/mixing/papers/Nature/nature_fig3.gif)
Figure: 3 (a) Centroid position
projected onto the material's centerline for an experiment at f = 0.30. The
centroids' positions are taken relative to that of the whole material and
normalized to one initially. When the material is perfectly mixed, the color
centroids coincide with each other at the origin. The centroids are measured
through digital pictures taken as the disk rotates. The same algorithm computes
experimental and simulated centroid positions. Dots are experimental data; solid
lines are a fit to exp(-gt)cos(2pit/T) with g = 1.1 +/- 0.2, T = 0.37 +/- 0.02,
both in units of revolutions. The exponential envelopes are emphasized by dashed
lines. (b) The mixing rate g versus fill level f. Open symbols are obtained from
fits to simulated data from the model; filled symbols are experiments. For f
> 1/2 the core is removed from the calculation of g. The inset shows gamma
the volume mixed per characteristic time versus f. The experimental (calculated)
optimum is f = 0.23
(f = 0.25).
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![[square comparisons]](http://pg.chem-eng.nwu.edu/mixing/papers/Nature/nature_fig4.gif)
Figure: 4 Granular mixing in a
square after 1-1/4 revolutions. Simulation on top; experiment on bottom. The
experiments are initialized as in Fig. 1; here the salt is dyed red and yellow.
The simulation here includes a thin layer of thickness e = 10 grains outside of
the core to account for the boundary mentioned earlier.
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