Long Ion Mean-Free Path and Nonequilibrium Radiation Effects on High-Aspect-Ratio Laser-Driven Implosions

1 May 1989

journal article
research article
Published by Cambridge University Press (CUP) in Laser and Particle Beams

Vol. 7 (2), 259-265
https://doi.org/10.1017/s0263034600006029

Abstract

The implosion dynamics of experiments with high-aspect-ratio laser-driven targets are re-examined by taking account of long ion-mean-free paths. The mean-free path is found to be comparable to the fuel size and this can cause a significant departure from a fluid-like description. One of such effects stemming from the long ion-mean-free path; namely, real viscosity, seriously changes the results; the compression ratio becomes 5 times smaller with this real viscosity. In addition to this, inclusion of non-LTE (local thermodynamic equilibrium) atomic process is shown to critically determine the implosion dynamics because of bound-free opacity associated with a small fraction of hydrogen-like ions.

Keywords

This publication has 12 references indexed in Scilit:

High-Aspect-Ratio Laser-Fusion Targets Driven by 24-Beam uv Laser Radiation
Physical Review Letters, 1986
Laser Implosion of High-Aspect-Ratio Targets Produces Thermonuclear Neutron Yields Exceeding $10^{12}$ by Use of Shock Multiplexing
Physical Review Letters, 1986
Laser implosion of microballoons: study of the transition from exploding-pusher to ablative regime
Nuclear Fusion, 1984
Ion Beam Pulse Compression by Its Conversion into Soft X-Ray
Japanese Journal of Applied Physics, 1984
Influence of high-energy ion loss on DT reaction rate in laser fusion pellets
Nuclear Fusion, 1979
Rayleigh-Taylor instabilities in inertial-confinement fusion targets
Nuclear Fusion, 1977
Laser Compression of Matter to Super-High Densities: Thermonuclear (CTR) Applications
Nature, 1972
Production of Thermonuclear Power by Non-Maxwellian Ions in a Closed Magnetic Field Configuration
Physical Review Letters, 1971
Cross Sections for the Reactions $D (d, p) T$ , $D (d, n) {He}^{3}$ , $T (d, n) {He}^{4}$ , and ${He}^{3} (d, p) {He}^{4}$ below 120 kev
Physical Review B, 1954
A Method for the Numerical Calculation of Hydrodynamic Shocks
Journal of Applied Physics, 1950

Cited by 11 articles