论文信息 - Laser-driven isentropic hollow-shell implosions: the problem of ignition

Laser-driven isentropic hollow-shell implosions: the problem of ignition

It is shown that a relatively weak initial shock introduced into an otherwise isentropic hollowshell implosion can cause central fuel ignition, the bulk of the fuel undergoing little increase in entropy. The imploded-state fuel configuration is analysed at the threshold of ignition, and it is found that electron heat conduction is the predominant cooling mechanism opposing fuel ignition. Approximate temperature-dependent ρR requirements are presented for the conduction-limited ignition of thin DT shells, and for the equality of electron heat conduction and α-particle transport in thermonuclear burn propagation.

R. Kidder

[1] V. Rozanov,et al. Similarity solution of thermonuclear burn wave with electron and α-conductivities , 1976 .

[2] J. Nuckolls,et al. Laser Compression of Matter to Super-High Densities: Thermonuclear (CTR) Applications , 1972, Nature.

[3] R. Kidder,et al. Laser-driven compression of hollow shells: power requirements and stability limitations , 1976 .

[4] A. Sakurai. ON THE PROBLEM OF A SHOCK WAVE ARRIVING AT THE EDGE OF A GAS , 1960 .

[5] R. Kidder,et al. Energy gain of laser-compressed pellets: a simple model calculation , 1976 .

[6] Numerical simulation of the high density approach to laser-fusion , 1973 .

[7] Laser-induced compression of thin shells and uniform spheres - A theoretical comparison , 1976 .