DocumentCode
1707400
Title
Numerical modeling of ICF plasmas
Author
Dahlburg, J.P. ; Gardner, J.H. ; Schmitt, A.J. ; Colombant, D. ; Klapisch, M. ; Phillips, Linsey
Author_Institution
Div. of Plasma Phys., Naval Res. Lab., Washington, DC, USA
fYear
1999
Firstpage
95
Abstract
Summary form only given, as follows. Radiation transport hydrodynamics codes play an important role in the design and development of ignition-regime and high-gain direct drive inertial confinement fusion (ICF) pellets. In this concept, laser light is used to symmetrically implode a spherical pellet to sufficiently high densities and temperatures to achieve thermonuclear fusion. This requires a very symmetric illumination and a stable hydrodynamic implosion. Simulations of the dynamics of both planar and spherical targets are being performed to provide better understanding of how to control the Rayleigh-Taylor (RT) instability, using the 1-, 2- and 3-dimensional laser matter interaction (LMI) code FAST. To benchmark FAST, and the super transition array material opacities used in the pellet design simulations, comparisons are being made with experimental data obtained in planar LMI experiments on the Naval Research Laboratory Nike KrF laser. One of the major efforts is to understand the behavior of the RT instability in planar laser-accelerated targets. Since this is one of the primary obstacles to successful ICF, experimental comparison is not only providing for code benchmarking, but will also lead to a better understanding of how to control this basic instability. Code benchmarking is also being performed using data from Nike opacity experiments, and from equation of state experiments in ICF-relevant regimes.
Keywords
Rayleigh-Taylor instability; laser fusion; plasma instability; FAST laser matter interaction code; ICF plasmas; Nike KrF laser; Nike opacity experiments; Rayleigh-Taylor instability; code benchmarking; equation of state; high-gain direct drive inertial confinement fusion pellets; hydrodynamic implosion; ignition-regime; laser light; numerical modeling; pellet design simulations; planar laser-accelerated targets; radiation transport hydrodynamics codes; spherical pellet symmetrical implosion; super transition array material opacities; thermonuclear fusion; Hydrodynamics; Inertial confinement; Laser fusion; Laser modes; Laser transitions; Numerical models; Plasma confinement; Plasma density; Plasma temperature; Plasma transport processes;
fLanguage
English
Publisher
ieee
Conference_Titel
Plasma Science, 1999. ICOPS '99. IEEE Conference Record - Abstracts. 1999 IEEE International Conference on
Conference_Location
Monterey, CA, USA
ISSN
0730-9244
Print_ISBN
0-7803-5224-6
Type
conf
DOI
10.1109/PLASMA.1999.829292
Filename
829292
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