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Granular materials, complex nonlinear pattern formation, and control
of complex patterns are at the forefront of our understanding of
collective behavior. The study of granular materials
provides insight into poorly understood and vitally important
industrial problems, and an unprecedented opportunity to investigate
experimentally the theoretical underpinnings of statistical physics.
In granular systems, collective behavior and pattern formation can
occur with a small number of macroscopic particles. This property
creates a unique opportunity to gain a fundamental understanding of
mesoscopic systems, such as colloids, lubrication, and nanoscale
porous media. Pattern formation in granular systems illustrates the
profound link between granular flows and ordinary
fluids and is a cornerstone of our research.
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Experimental tests of granular kinetic theory: We conduct
experiments to directly test granular kinetic theory in the
laboratory. Using high speed digital photography, we track the
position a velocity of individual grains in a 2D rotating drum. At
moderate rotation rates three flow regimes are formed --- a dilute gas
at the top, a dense gas in the middle, and a elasto-plastic solid at
the bottom. In earlier work, we have confirmed that continuum
equations of motion derived using kinetic theory of dense inelastic
gases give quantitative results for the dilute phase. We are now
exploring their applicability to the dense phase, where we may
encounter visco-elastic behavior, which is not currently included in
the theory. Finally we are exploring ways of extending kinetic theory
and connecting with elasto-plastic solid models to bring the entire
flow regime under a unified theory.
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Experimental granular rheology: By uniformly exciting a
granular media using a random sum of its container's elastic
vibrational modes, we can directly measure the speed of sound, thermal
conductivity, and viscosity as a function of density and granular
temperature in this uniformly heated steady-state. Using a
sinusoidally varying forcing we can measure the frequency dependence
of the transport properties.
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Granular media as an analog for collective systems in extreme
conditions: We will study the flow of uniformly heated granular media
in a small channel as an analog for mesoscopic systems. We can
explore phase transitions in systems of rods, in mixtures of rods and
spheres, and in mixtures of different sized spheres. These studies
will add to the understanding of both granular media and ordinary
condensed matter under extreme situations including confined
geometries, gradients which are large on the scale of the mean free
path, and flow in which intrinsic mechanical stress can induce phase
transitions.
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Granular pattern formation: A vertically oscillated and
uniformly heated granular layer provides a strong analogy with
ordinary fluids. By varying the amount of external heating a
continuous range of behavior, from fluid-like at high temperature, to
granular at zero external heat flux, can be studied. In the unheated,
vibrated granular layer extremely large scale patterns can be produced
with up to 500 wavelengths.
Organisms adapted for motion on beaches and in deserts show amazing
mobility in a variety of surface conditions. Long term adaptation of
these animals to shifting sand provides a great opportunity to
understand the optimal general principles of legged locomotion.
Nature has not developed wheeled motion, and legged animals like
spiders, crabs, and lizards provide an existence proof that rapid
locomotion in flowing environments is possible. There is increasing
evidence that motion on complex terrain rely on both active and
passive control. To that end we are developing micro-robots with legs
that are based on principles of real organisms to leverage the passive
mechanical aspects of real organisms. The long term goal is to
produce autonomous robots of 1-10cm in size, that can run on general
terrain at speed up to 10 body-lengths-per-second. We are currently
working on anatomically accurate leg design using 3D printing, for
rapid prototyping, and nitinol memory wire as muscles.
The study of pattern formation has produced an understanding of simple
bifurcations to single-patterned states in spatially extended
systems. Patterns in nature, however, display a
complexity which defies this basic understanding. We will push the
study of pattern formation to a new level of complexity using novel
experimental techniques to study systems which combine large numbers
of spatial modes with pattern competition and spatiotemporal
inhomogeneous forcing. Further, we will use spatiotemporal
perturbations to control patterns and stabilize them beyond their
normal range of stability. This is a prerequisite step for control of
complex pattern formation in industrial processes, and control of
natural systems such as weather, evolution, and thought.
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Complex nonlinear pattern formation and control: We will
explore complex nonlinear pattern formation in binary mixture
Rayleigh-Benard convection. We can measure the density and
concentration fields using a novel visualization technique based on
the preferential absorption of infrared laser-light by one component
of the mixture. We can systematically add complexity to this system
by increasing the number of spatial modes through changes in aspect
ratio and inclusion of pattern competition. We will combine
visualization and arbitrary spatiotemporal perturbations using a
high-powered laser rastering system to form a closed loop control
system. Previously, control of simple pattern forming systems with a
small number of spatial modes has been achieved in the laboratory
using both linear and nonlinear control, but we will extend both
methods to control complex pattern formation.
We need students to work on the experimental projects listed below,
which are planned for 2012. In addition we have a
number of molecular dynamics and continuum simulation project which
could be explored. If you are interested please contact
Mark Shattuck.
- Bio-Inspired Micro-Robot Leg
Design and Testing: We will use commercially available 3D
printing services to produce small 1-5cm articulating robot legs
based on desert spiders and crabs. Nitinol memory wire will be used
for antagonistic muscles.
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determination of the Speed of Sound in granular materials: If
sufficient energy is injected into granular materials then they can
flow like a Newtonian fluid. However, due to the energy loss during
collisions between grains the granular temperature can be quite low
leading to a very low speed of sound in the material. We will measure
the speed of sound in a 2D horizontal granular layer excited from two
sides by creation of standing waves perpendicular to the excitation.
- Granular pattern
formation with extremely large aspect ratio: A vertically
oscillated granular layer can produce a wide range of patterns. We
will explore the effect of container size on the pattern formation by
vibrating extremely large granular layers, which can creating patterns
with up to 500 wavelengths.
- Effect of tool angle
on fracture pattern in polymer sheets: Pulling a tool through
a cellulose sheet creats a distinctive pattern which depends on the
size of the tool but is independent of the rate of pulling. We will
explore the dependence of the pattern on the angle of the tool using
an existing experimental setup.
