Tracking the density evolution in counter-propagating shock waves using imaging X-ray scattering

U Zastrau ,Andreas Schropp ,L B Fletcher ,Eric Galtier ,R W Falcone ,J B Hastings ,K Falk ,R P Drake ,Bob Nagler ,E J Gamboa ,Jian Lü ,P Heimann ,Eduardo Granados ,B Tobias ,P A Keiter ,S H Glenzer ,D S Montgomery ,D Kraus ,M Gauthier ,K W Hill ,N Pablant ,Dirk O Gericke ,M J Macdonald ,J.f Benage ,P C Efthimion ,H J Lee

doi:10.1063/1.4959256

Tracking the density evolution in counter-propagating shock waves using imaging X-ray scattering

U Zastrau , Andreas Schropp + Show 24 more

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https://doi.org/10.1063/1.4959256

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Journal: Applied Physics Letters	Publication Date: Jul 18, 2016
Citations: 12	License type: publisher-specific, author manuscript

Affiliation: European X-Ray Free-Electron Laser, SLAC National Accelerator Laboratory, Menlo School, Deutsches Elektronen-Synchrotron DESY, University of California, Berkeley, Los Alamos National Laboratory, Czech Academy of Sciences, Institute of Physics, University of Michigan–Ann Arbor, Princeton Plasma Physics Laboratory, University of Warwick, Sandia National Laboratories

#Laser-driven Shock Waves #Time-resolved X-ray Imaging + Show 8 more

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Abstract

We present results from time-resolved X-ray imaging and inelastic scattering on collective excitations. These data are then employed to infer the mass density evolution within laser-driven shock waves. In our experiments, thin carbon foils are first strongly compressed and then driven into a dense state by counter-propagating shock waves. The different measurements agree that the graphite sample is about twofold compressed when the shock waves collide, and a sharp increase in forward scattering indicates disassembly of the sample 1 ns thereafter. We can benchmark hydrodynamics simulations of colliding shock waves by the X-ray scattering methods employed.

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