Post on 21-Jan-2016
Hydrodynamic Instabilities
in Laser Plasmas
Cris W. BarnesP-24
July 3, 2002
2
DEMONSTRATIONS•Why does water fall out of jar?
•Instability and stability
3
Plasmas as Fluids•This talk is about “fluid dynamics”•But I’m a plasma physicist….
•Plasma fluids:– Unmagnetized
– No E or B fields
– Highly collisional
– Can be treated as single species (“no electron physics”)
– Generally caused by application of high energy density to near-solid material (such as by shock)
– (Can be) Compressible
4
Fundamental Equations•Conservation of mass: particle balance•Conservation of momentum: force balance
(pressure balance)•Conservation of energy: energy balance
Ignoring time derivatives can define “hydrostatic equilibrium”.
Putting in time dependence and perturbing that equilibrium can analyze for stability.
5
Examples of Rayleigh-Taylor• ICF
•Geophysics (material strength)
6
Nonlinear behavior•What happens when ball hits floor?
•When mode amplitude is “significant fraction” of mode wavelength, the system become “nonlinear”.
•These instabilities generate “turbulence” and cause “mix”– ICF example
7
Nano-technology (both foam production and precision machining) is an enabling technology for cylindrical implosion hydrodynamics
Mix Region
Foam Core
Outer Ablator
Increasingly Nonlinear Hydrodynamics
“Mix”
“Features”, both single and periodic
Direct-drive cylinder target for OMEGA
8
Time resolved X-ray images provide substantial information from a single shot
polystyrene
C8H7Br
C8H6Cl2
CH2 foamphase reversal
l1.5 m initial amplitude; see trajectories, perturbation modal amplitudes, shock arrival, illumination asymmetry
9
Ambiguous image center allows choice that reveals Fourier spectrum with fundamental (m=10), illumination imprint (m=4), and weak nonlinear coupling (m=6 & 14)
+*
Choose image center to reduce±1 sidebands around fundamental
Plotting Imaginary vs Real part of FFT for each mode for eachframe: see well-defined phases
Varying phase betweenm=10 and 4 and applyingmode-coupling simulates“odd-shaped” data
10
More Stuff•Peter Wilson / Malcom Andrews Texas A&M
water tank experiment
This may be a “classic” field (Lords Kelvin and Rayleigh from the
Nineteenth Century) but cool stuff still possible today!
•Kelvin-Helmholtz•Richtmyer-Meshkov (impulsive)•Bell-Plesset (convergence matters)
CYLMIX and DNS calculations, and CYLART results from our own team
11
We’ve established a useful, laser-based test bed for compressible convergent mix experiments• Implode cylinder with direct laser
irradiation• Hydrodynamically unstable at
plastic/Au and Au/foam interfaces (now using epoxy/Al)
• Shine x rays through cylinder• Measure radial extent of “mix
layer” of Au or Al into adjacent materials
• 1D experiment with Mach number ≈ 10, convergence ≈ 3, Pressure > 45 Mbars
12
Experimental Results are compared to DNS (Direct Numerical Simulations) for different initial conditions
•Mix with rough initial conditions overwhelms end effects
•Differences exist between codes
•Both “bowing” and “filigree” exist
PETRA r-Z calculations
RAGE r-Z calculations
13
rrZ
rrZ
Mar
ker
Wid
th (
µm)
Time (ns)
0
20
40
60
80
100
120
140
160
0 1 2 3 4 5
RageRage PetraPetra Experiment
We have made measurements of mix growth in time with rough surface finish•Done on different shots
(OMEGA backlighter limitations) but with the same type of target
•Growth consistent with linear after shock breakout, and with DNS simulations
22602 3.2 nsFrames 3c
18687 4.7nsFrames 2c
14
Hydrodynamic Instability and Turbulent Mix
•Classic field of fluid dynamics studied world-wide at many institutions
8th International Workshop on the Physics of Compressible Turbulent Mixing was held in
Pasedena last December.•High Atwood number (“variable density,
inhomogeneous turbulence”), compressible (high energy density), convergent systems are at the forefront of challenging science at National Labs with new experimental and theoretical tools becoming available to study them.