Rayleigh-Taylor stabilization by material strength at Mbar pressures

Bruce Remington; Hye-Sook Park; Thomas Lorenz; Robert Cavaloo; Stephen Pollaine; Shon T. Prisbrey; Robert Rudd; Richard Becker; Joel Bernier

Rayleigh-Taylor stabilization by material strength at Mbar pressures

ORAL

Abstract

We present experiments on the Rayleigh-Taylor (RT) instability in the plastic flow regime of solid-state vanadium (V) foils at ~1 Mbar pressures and strain rates of 1.e6-1.e8 1/s, using a laser based, ramped-pressure acceleration technique. High pressure material strength causes strong stabilization of the RT instability at short wavelengths. Comparisons with 2D simulations utilizing models of high pressure strength show that the V strength increases by factors of 3-4 at peak pressure, compared to its ambient strength. An effective lattice viscosity of ~400 poise would have a similar effect. [1] Constitutive models, and theoretical implications of these experiments will be discussed. [1] H.S. Park, B.A. Remington et al., submitted for publication (July, 2009).

^*This work was performed under the auspices of the Lawrence Livermore National Laboratory under Contract No. DE-AC52-07NA27344.

Nov. 2, 2009, 3:48 PM – Nov. 2, 2009, 4:00 PM

Authors

Bruce Remington
- Lawrence Livermore National Laboratory
- LLNL
Hye-Sook Park
- LLNL, Livermore, CA 94550, USA
- Lawrence Livermore National Laboratory
- LLNL
Thomas Lorenz
- LLNL
Robert Cavaloo
- Lawrence Livermore National Laboratory
- LLNL
Stephen Pollaine
- LLNL
- Lawrence Livermore National Laboratory
Shon T. Prisbrey
- Lawrence Livermore National Laboratory
- LLNL
Robert Rudd
- LLNL
Richard Becker
- LLNL
Joel Bernier
- LLNL