Magnetic focusing and trapping of high-intensity laser-generated fast electrons at the rear of solid targets

The transport of fast electrons generated by a 1 ps, 20 J, 10(19) W cm(-2), 1 mu m wavelength laser pulse through 70-250 mu m thick deuterated polyeth ylene (CD2) targets is modeled with a Fokker-Planck hybrid code in r-z geom etry. Initially, electric field generation inhibits propagation, which then proceeds by the formation of a low resistivity channel due to Ohmic heatin g. The magnetic field generated at the edge of the channel leads to strong collimation. This is observed for a wide range of parameters. Reflection of electrons at the rear surface forms a magnetic held which focuses the inci dent electrons on to the rear surface and forces the reflected electrons ou twards. This would lead to the formation of a small diameter plasma on the rear surface, as observed in experiments. The reflected electrons are confi ned to a cone by a self-generated magnetic field, enhancing energy depositi on at the rear of the target. [S1063-651X(99)03705-8].