Title: Quasi-two-dimensional granular gas
1Unusual diffusion in quasi-two-dimensional
granular gas
Wennan Chen ??? and Kiwing To ???Institute of
Physics Academia Sinica????????
OUTLINE Introduction granular physics Velocity
distribution of granular gas Diffusion of
quasi-2D granular gas Phenomenological two-state
model Summary Discussions
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Give, and it shall be given unto you a good
measure, pressed down, shaken together, and
running over, they will give into your bosom.
For with what measure you measure, it shall be
measured to you in return.
New Testament Bible, Luke, 638
3Compaction demonstration
- Compaction demonstration video
4Granular Solid
- Force distribution at granular pile bottom
- Vanel et. al., PRE 60, R5040, 1999
pile of sand 1.2 mm diameter 8 cm high 33o repose
angle
localized deposition
uniform deposition
5Granular Solid
- apparent weight
- Vanel, Duran, 97
cylinder radius (mm) 20 bead diameter (mm) 1.5,
2, 3
Where has the missing weight gone?
6Granular Solid
- physical properties are history dependent
density increases due to rearrangement of beads
in packing
Potential energy of a grain
mgd with m 10-2 g, g10m/s2, d1mm 10-7 J
Thermodynamic temperature kT with
k1.38?10-21 J/K, T300K 4?10-21 J
Temperature 0 as compared to granular
energy Thermodynamically non-equilibrium,
meta-stable state
does not relaxes spontaneously relaxes by
external agitation (tapping or vibration)
7Static and dynamicsdead and alive
gas fluid solid
dense, slow flow
quasi-static meta-stable glassy region
8Motivation
Statistical properties of quasi-two-dimensional ga
s with inelastic inter-molecular interaction
gas a collection of small molecules moving
around
inter-molecular interaction exchange of energy
among molecules
inelastic interaction does not conserve energy
statistical properties velocity
distribution temperature diffusion
constant
9hard sphere collision
10elastic collision
from equilibrium statistic mechanics
Maxwell distribution
change in velocity distribution due to collision
Boltzmann Equation
11inelastic collision
12inelastic hard spheres
velocity distribution changes due to collision
Boltzmann-Enskog Equation
collision integral
van Noije and Ernst, Gran. Matter 1, 57, 1998.
13inelastic hard spheres
ltlt
exponential decay at high energy tail
confirmed by direct Monte Carlo simulation Brey,
et. al., PRE 59, 1256, 1999.
14velocity distribution and temperature
molecular gas
elastic collisions
in equilibrium state
temperature
inelastic collisions
granular gas
non-equilibrium steady state
for c gtgt 1
granular temperature
15Unusual diffusion in quasi-two-dimensional
granular gas
MSD 6 D t
diffusion constant
in 2 dimension MSD 4 D t
in 1 dimension MSD 2 D t
16Unusual diffusion in quasi-two-dimensional
granular gas
diffusion constant m2/s
D inversely proportional to N
usual diffusion
17Unusual diffusion in quasi-two-dimensional
granular gas
granular gas a collection of molecules
interact with each other with inelastic
collision
quasi-two-dimensional two dimensional
projection from three dimensional motion
plastic ball diameter 6 mm mass 0.12
gm vibration frequency 20 Hz amplitude
1.84 mm camera resolution 1024x1024 frame
rate 1000 fps
18Unusual diffusion in quasi-two-dimensional
granular gas
get trajectory each particles
measure MSD
19MSD 4D t
diffusive motion
MSD lt(Dx)2gt lt(vt)2gt ltv2gt
t2
ballistic motion
N 1000
slope2
20N 500
D300 mm/s2
N 1000
D100 mm/s2
214D mm2/s
diffusion increases with N for N lt 1000
Tg 10-9 J
N
22ball dynamics
motion in vertical direction
motion in horizontal direction
collision with top or bottom (type-1)
collision with other balls (type-2)
small velocity fluctuation in horizontal
direction
large velocity fluctuation in horizontal
direction
balls may gain kinetic energy in the horizontal
direction due to inelastic collision
top and bottom act on the balls like a viscous
fluid
23particle trajectory and speed
high speed state
low speed state
24Two state model
ball excited to HSS after colliding with another
ball
ball in HSS relaxes to LSS in t2 due to collision
with top and bottom
1800
500
200
50
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26total area swept
27fraction of ball in HSS
argument break down when ft 1, this happens
when N Nc 945
28Two effect temperature baths
collision with other ball
collision with top or bottom
temperature bath-2, T2
temperature bath-1, T1
effective granular temperature
29Summary and discussions
We studied diffusion in a quasi-two-dimensional
granular gas (Q2DGS) composed of plastic balls
confined in a vertically vibrating thin box.
The motion of the particles in the Q2DGS was
found to follow the Langevin equation with the
top and bottom of the box acting on the balls
like a viscous fluid.
We found that both the granular temperature and
the diffusion constant increased with the number
of balls N in the box for small N.
Based on the velocity distributions and the two
different kinds of horizontal motions observed in
the experiments, we proposed a simple two-state
model to explain the unusual diffusion behavior.
Thank you for your attention !
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31Motivation
Can we understand the statistical properties of
granular gas using simple kinetic theory ?
kinetic theory each molecule move according
to Newtons law
statistical properties velocity
distribution temperature diffusion
constant