iaea chengdu , oct 2006
DESCRIPTION
Studies of isochoric heating by electrons and protons. IAEA Chengdu , Oct 2006. Andrew MacKinnon. Plus. Rapport: Papers IF/1 -R2b and 1F/1 - R2c. - PowerPoint PPT PresentationTRANSCRIPT
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IAEA
Chengdu , Oct 2006
Andrew MacKinnon
This work was performed under the auspices of the U.S. Department of Energy by University of California Lawrence Livermore National Laboratory under contract No. W-7405-Eng-48.
Studies of isochoric heating by electrons and protons
Rapport: Papers IF/1 -R2b and 1F/1 - R2c
Plus
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Co -authors and acknowledgements
K. Akli, F. Beg, M.H. Chen, H-K Chung, M Foord, K. Fournier, R.R. Freeman, J. S. Green, P. Gu, J. Gregori, H. Habara, S.P. Hatchett, D. Hey, J.M. Hill
J.A. King, M.H. Key, R. Kodama, J.A. Koch, M Koenig, S. Le Pape, K. Lancaster, B.F.Lasinski, B. Langdon, S.J. Moon, C.D. Murphy,, P.A. Norreys, N. Patel, P.K Patel, H_S.Park, J. Pasley , R.A. Snavely, R.B. Stephens, C Stoeckl, M Tabak,
W. Theobold, K. Tanaka, R.P. Town, S.C. Wilks, T. Yabuuchi, B Zhang,
• This work is from a US Fusion Energy Program Concept Exploration and Advanced concept exploration collaboration between LLNL, General Atomics, UC Davis, Ohio State, UCSD and LLE
• International collaborations at RAL,LULI and ILE have enabled most of the experiments
• Synergy within LLNL, through ‘Short Pulse’ S&T Initiative has helped the work
• US collaboration in FI has recently expanded in a new Fusion Science Centrelinking 6 Universities and GA with LLNL and LLE and a new Advanced Concept Exploration project between LLNL,LLE,GA, UC Davis , Ohio State and UCSD
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Fast Ignition entails assembly of compressed fuel followed by fast heating by MeV particles
Ignition driver: short pulse laserCompression
driver: Laser
Step 1. Compress fuel
critical surface
Step 2. Ignite fuel
Initial concept utilized kJ source of MeV electrons in picosecond pulse to ignite imploded capsule ( M. Tabak et al., Phys Plasmas 1, 1626, 1994)
MeV particles
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Success in fast ignition requires a very large flux of MeV particles to be deposited in 10-20ps
Electron Fast Ignition1
Cone protects ignitor pulse from coronal plasma Laser conversion to fast electrons ~ 30% ~ 60 kJ laser energy required Electron transport most important issue
Proton Fast Ignition2
Currently laser conversion into protons ~10% ~180 kJ laser energy required Improving proton conversion efficiency most important issue
(1)Atzeni et al.,PoP (1999)(2) Roth et al.,86,436 PRL 2000, Atzeni et al., 2002; Temporal et al., PoP 9,3102 (2002)
• FI (1,2) requirements: heat 300 g/cc, (R~2.5 g/cm2) with 18-20 kJ particles at MeV energy in 10 ps over 30-40 m dia.
PW laser
Laser
•DT fuel at 300g/cc• 35 m ignition spot
Coronal Plasma
Cone•DT fuel at 300g/cc•40 m ignition spot
MeV electrons
MeV protons
Laser
Laser
Curved proton rich target
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There is wide-ranging research in high intensity physics related to Fast Ignition in institutions around the world
15%coupling
30%coupling
Kodama,et.al,Nature 412(2001)798 and 418(2002)933.
Results from Institute for Laser Engineering, Osaka have shown promise of cone focused scheme
• Existing experimental Facilities: United Kingdom,France, LLNL(Titan), SNL, Universities,…• Theory: US, UK, France, Germany, Italy, Japan, China, India• Upcoming Facilities: Omega EP(Rochester), NIF ARC(LLNL), FIREX I(Japan)• Proposed facilities : HIPER(Europe), FIREX II(Japan), China
Implosion beams300 TW laser
“Cone” implosions
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Cone wire targets are being used to study electron transport at FI relevant laser intensities
1m 10 m
256 XUV • Cone/Wire represents conductivity channel in FI scheme: test-bed for existing electron transport models
• K emission images show 100m exponential scalength
• Bell 1D analytic model* gives similar scale-length to experiment
• Peak temperature measured by XUV imaging to be 350 eV with 100 m scale length ~ 1.2% of laser energy
• 1D numerical model injecting 1.2% of laser energy as hot electrons matches observed K
•1D transport scaling gives 20% coupling at 40 m diameter - This would be viable for FI
1.E+08
1.E+09
1.E+10
1.E+11
0 500 1000
Micron
Kalp
ha p
ho
t/m
icro
n
Experimental data
Bell 1D Ohmic modelNe arb units Transport model
* A.R.Bell et al., Cont Plasma 1997
Target 10mCu wire /Al cone
500 µm
Cu K
1 mm 1mm
RAL PW laser Vulcan
Laser 500 J, 0.8 ps
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Al+4
Hot e
C+6Thermal e
H+
Fra
ctio
n o
f In
ject
ed E
ner
gy
Refluxing hot e5m Al substrate
0.1m CH4 layer
Electrons
Proton FI: Proton conversion efficiency optimized by reducing target thickness and increasing hydrogen fraction on surface
Refluxing hot electrons continuously lose energy to thermal ions and electrons in substrate Contaminant layer containing hydrogen ionized & accelerated by MeV/m electric field Reducing target thickness increase conversion efficiency as hot electron pressure increases Increasing proportion of H+ in layer increases conversion eff -> hydrides or pure H2 should provide highest conversion efficiency
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Varying Z of hydride layer could yield factor 2-3 enhancement in proton conversion efficiency
0
10
20
30
40
Hydrides
BC
Ho
t el
ectr
on
co
nve
rsio
n e
ffic
ien
cy (
%)
H LiH CHn
MgH2
CaH2
CsH ErH3
UH3
CH4
CH2
CH
HZ
ZHn
Thot=880keV5 m Au + 1000 ZH
n
Current experiments with contaminant layers
Cryogenic H2
• Experiments planned for mid FY07
Efficiency simulations for hydrides
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Shot No:060622_s1:
20µm thick, 350µm Diameter Al hemi-shell with 25µmx25µm Cu mesh at 1mm spacing
RCF pack for measuring proton dose
This technique allows simultaneous determination of location of proton focus, size of proton spot and extent of heated region
Proton focusing: Mesh imaging of the proton beam provides great deal of information on focusing mechanism
Fine mesh w/ element separation = 25m
Laser : spot~50µm
1mm
Focal Plane
70mm
x
Equatorial Plane
d
Oblique view XUV Imagers at 68 and 256eV to measure size of heated region
Side view
d = 250m
Laser view
mesh
mesh
LaserView of xuv
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Mesh image and XUV emission from the proton heated mesh indicates very small proton spot (~30-50m)
• 68eV image shows very bright image and large plume - consistent with high Temp
• 256 eV image also shows ~30-50m heated region
• RCF shows 3-4 mesh elements in 20MeVproton beam - agrees well with 256eV image
• Data is being used to test proton focusing models
256eV XUVLaser
30m
Proton dose (20MeV)
68eV XUV
30m
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User experiments will begin in 2008
Integrated experiments are being planned for Omega EP: These will test fast ignition concepts at kJ short pulse energy levels
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2 x1.2 kJ per beam line One beam line in FY09 (Option for 13 kJ quad)
Fast ignition experiments can also be carried out onthe NIF using the high energy radiography beams
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• Paper IF/1 -2b: R. Kodama et al., “ Plasma photonic devices for Fast Ignition Concept in Laser Fusion Research”
• Paper 1F/1 - 2c: K. Tanaka et al., “Relativistic Electron Generation and its behaviors Relevant to Fast Ignition”
Rapport: Papers IF/1 -R2b and 1F/1 - R2c
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• Paper IF/1 -2b: Describes how cones and other guiding devices modify Electron generation in FI
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Cones appear to strongly collimate MeV electrons into beams
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Integrated experiments show plasma heating by short pulse, consistent with collimated electron beams
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Please see poster IF/1-2Rb for full paper
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Relativistic Electron Generation and Its Behaviors Relevant to Fast Ignition
K. A. Tanaka1,2, H. Habara1,2, R. Kodama1,2, K. Kondo1,2, G.R.
Kumar1,2,3, A.L. Lei1,2, K. Mima1, K. Nagai1, T. Norimatsu1, Y. Sentoku4, T. Tanimoto1,2, and T. Yabuuchi1,2
1Institute of Laser Engineering, Osaka University,2-6 Yamada-Oka, Suita, Osaka 565-0871 Japan
2Graduate School of Engineering, Osaka University,2-1 Yamada-Oka, Suita, Osaka 565-0871 Japan
3Tata Institute of Fundamental Research,Homi Bahbha Rd., Mumbai 400 004 India
4 Department of Physics, University of Nevada, Reno, Nevada 89521-0042 U.S.A.
IF/1-2Rc
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• To increase the heating efficiency of the core plasma, we propose a foam cone-in-shell target design.
Target design improvement: foam cone-in-shell target for increasing the heating efficiency of core plasma
Multiple implosion beams
Relativistic laser
Gold cone with inner tip covering with a foam layer
Fuel shell
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Au foam coating enhances laser absorption and hot electron generation
F r o n t X P H C B a c k X P H C
G X I I P W l a s e r
T a r g e t
E l e c t r o n s p e c t r o m e t e r
a
c
d
b
0 2 5 0 0 5 0 0 0
e
F r o n t
F r o n t
B a c k
B a c k
F o a m c o a t i n g
S o l i d c o a t i n g
F o a m c o a t i n g
S o l i d c o a t i n g
•Hot -e yield measurement via the back x-ray emission from the target rear due to the heating from hot –e beams
-weak front x-ray emission from the Au foam-coated target. This is due to the low density of the foam.
-stronger back x-ray emission from the Au foam coated target. This is attributed to higher laser absorption and more hot electrons generated with the foam coated target. Back x-ray emission is caused by the hot –e beam heating of the target rear.
-target is thick so that the front x-ray emission may not be responsible for the enhancement of back x-ray emission with foam coated target. Moreover, if it happens, one would expect weak x-ray emission from the foam coated target rear, contrary to the experimental results.
-narrow band-width x-ray image diagnostics needed to give the relative hot –e yield through assuming Plankian emission from the target rear.
-quantitative models and simulations needed
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Surface Acceleration of Fast Electrons with Relativistic Self-Focusing in Preformed Plasma
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Hot electron distribution differs for with and without plasmas.
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PIC simulation shows surface hot electrons at 1019 W/cm2
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• We propose a foam cone-in-shell target design aiming at improving the cone-in-shell target design to increase the laser energy deposition in the dense core plasma.
• Our element experiment results demonstrated increased laser energy coupling efficiency into hot electrons without increasing the electron temperature and beam divergence with foam coated targets in comparison with solid targets. This may enhance the laser energy deposition in the compressed fuel .
• Phys. Rev. Lett., A.L.Lei, K.A. Tanaka et al., 96, 255006(2006).
Summary I
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Summary II
Surface direction hot electrons observed at oblique incidence UIL
experiment.
Relativistic laser self-focusing increases laser intensity causing
surface hot electrons.
Several tens of MGauss field inferred
H. Habara, K.A. Tanaka et al., Phys. Rev. Lett. 97, 095004(2006).
Please see poster IF/1- 2Rc for more details