Your search keyword '"Swadling, G.F."' showing total 2 results

1. Counter-propagating radiative shock experiments on the Orion laser and the formation of radiative precursors.

Author

Clayson, T., Suzuki-Vidal, F., Lebedev, S.V., Swadling, G.F., Stehlé, C., Burdiak, G.C., Foster, J.M., Skidmore, J., Graham, P., Gumbrell, E., Patankar, S., Spindloe, C., Chaulagain, U., Kozlová, M., Larour, J., Singh, R.L., Rodriguez, R., Gil, J.M., Espinosa, G., and Velarde, P.

Abstract

We present results from new experiments to study the dynamics of radiative shocks, reverse shocks and radiative precursors. Laser ablation of a solid piston by the Orion high-power laser at AWE Aldermaston UK was used to drive radiative shocks into a gas cell initially pressurised between 0.1 and 1.0 bar with different noble gases. Shocks propagated at 80 ± 10 km/s and experienced strong radiative cooling resulting in post-shock compressions of ×25 ± 2. A combination of X-ray backlighting, optical self-emission streak imaging and interferometry (multi-frame and streak imaging) were used to simultaneously study both the shock front and the radiative precursor. These experiments present a new configuration to produce counter-propagating radiative shocks, allowing for the study of reverse shocks and providing a unique platform for numerical validation. In addition, the radiative shocks were able to expand freely into a large gas volume without being confined by the walls of the gas cell. This allows for 3-D effects of the shocks to be studied which, in principle, could lead to a more direct comparison to astrophysical phenomena. By maintaining a constant mass density between different gas fills the shocks evolved with similar hydrodynamics but the radiative precursor was found to extend significantly further in higher atomic number gases (∼4 times further in xenon than neon). Finally, 1-D and 2-D radiative-hydrodynamic simulations are presented showing good agreement with the experimental data. [ABSTRACT FROM AUTHOR]

Published

2017

2. The production and evolution of multiple converging radiative shock waves in gas-filled cylindrical liner z-pinch experiments.

Author

Burdiak, G.C., Lebedev, S.V., Drake, R.P., Harvey-Thompson, A.J., Swadling, G.F., Suzuki-Vidal, F., Skidmore, J., Suttle, L., Khoory, E., Pickworth, L., de Grouchy, P., Hall, G.N., Bland, S.N., Weinwurm, M., and Chittenden, J.P.

Subjects

RADIATION, SHOCK waves, Z-pinch, LASER interferometry, OPTICAL spectroscopy, ENERGY density

Abstract

Abstract: A cylindrical liner z-pinch configuration has been used to drive converging radiative shock waves into different gases. On application of a 1.4 MA, 240 ns rise-time current pulse, a series of cylindrical shocks moving at typical velocities of 20 km s−1 are consecutively launched from the inside liner wall into an initially static gas-fill of density ∼10−5 g cm−3. The drive current skin depth calculated prior to resistive heating was slightly less than the liner wall thickness and no bulk liner implosion occurred. Axial laser probing images show the shock fronts to be smooth and azimuthally symmetric, with instabilities developing downstream of each shock. Evidence for a radiative precursor ahead of the first shock was seen in laser interferometry imaging and time-gated, spatially resolved optical spectroscopy. The interferometry diagnostic was able to simultaneously resolve the radiative precursor and the density jumps at the shock fronts. Optical streak photography provided information on shock timing and shock trajectories and was used to gain insight into the shock launching mechanisms. [Copyright &y& Elsevier]

Published

2013