Three-dimensional hydrodynamic experiments on the National Ignition Facility

The production of supersonic jets of material via the interaction of a strong shock wave with a spatially localized density perturbation is a common feature of inertial confinement fusion and astrophysics. The behavior of two-dimensional (2D) supersonic jets has previously been investigated in detail [ J. M. Foster , B. H. Wilde , P. A. Rosen , T. S. Perry , M. Fell , M. J. Edwards , B. F. Lasinski , R. E. Turner , and M. L. Gittings , Phys. Plasmas 9 , 2251 ( 2002 ) ]. In three dimensions (3D), however, there are new aspects to the behavior of supersonic jets in compressible media. In this paper, the commissioning activities on the National Ignition Facility (NIF) [ J. A. Paisner , J. D. Boyes , S. A. Kumpan , W. H. Lowdermilk , and M. Sorem , Laser Focus World 30 , 75 ( 1994 ) ] to enable hydrodynamic experiments will be presented as well as the results from the first series of hydrodynamic experiments. In these experiments, two of the first four beams of NIF are used to drive a 40 Mbar shock wave into millimeter scale aluminum targets backed by 100 mg ∕ cc carbon aerogel foam. The remaining beams are delayed in time and are used to provide a point-projection x-ray backlighter source for diagnosing the three-dimensional structure of the jet evolution resulting from a variety of 2D and 3D features. Comparisons between data and simulations using several codes will be presented.