Shock-driven discrete vortex evolution on a high-Atwood number oblique interface.

Authors :: Rasmus, A. M.
Di Stefano, C. A.
Flippo, K. A.
Doss, F. W.
Kline, J. L.
Hager, J. D.
Merritt, E. C.
Desjardins, T. R.
Wan, W. C.
Cardenas, T.
Schmidt, D. W.
Donovan, P. M.
Fierro, F.
Martinez, J. I.
Zingale, J. S.
Kuranz, C. C.
Source :: Physics of Plasmas. 2018, Vol. 25 Issue 3, p1-1. 1p. 2 Diagrams, 1 Chart, 4 Graphs.
Publication Year :: 2018
Abstract: We derive a model describing vorticity deposition on a high-Atwood number interface with a sinusoidal perturbation by an oblique shock propagating from a heavy into a light material. Limiting cases of the model result in vorticity distributions that lead to Richtmyer-Meshkov and Kelvin-Helmholtz instability growth. For certain combinations of perturbation amplitude, wavelength, and tilt of the shock, a regime is found in which discrete, co-aligned, vortices are deposited on the interface. The subsequent interface evolution is described by a discrete vortex model, which is found to agree well with both RAGE simulations and experiments at early times. [ABSTRACT FROM AUTHOR]

Subjects :: *SHOCK waves
*QUANTUM perturbations
*RICHTMYER-Meshkov instability
*WAVELENGTHS
*COMPUTER simulation
*HELMHOLTZ free energy

Full Text Access

Tools