Experiments of the highly non-linear Rayleigh-Taylor instability regime and dependence on Atwood Number

ORAL

Abstract

Potential flow models predict that a Rayleigh-Taylor unstable system will reach a terminal velocity (and constant Froude number) at low Atwood numbers. Numerical simulations predict a re-acceleration phase of Rayleigh-Taylor Instability (RTI) and higher Froude number at late times. To observe this effect, we are conducting a series of experiments at OMEGA 60 to measure single-mode RTI growth at low and high Atwood numbers and late times. X-ray radiographs spanning 40$+$ ns capture the evolution of these systems. Experimental design challenges and initial results are discussed here. This work is funded by the Lawrence Livermore National Laboratory under subcontract B614207, and was performed under the auspices of the U.S. Department of Energy by Lawrence Livermore National Laboratory under Contract No. DE-AC52-07NA27344.

Authors

  • L. Elgin

    University of Michigan

  • Timothy Handy

    University of Michigan, Univ of Michigan - Ann Arbor

  • Guy Malamud

    University of Michigan; Nuclear Research Center – NEGEV, Israel, Nuclear Research Center-Negev, University of Michigan

  • Channing M. Huntington

    Lawrence Livermore National Laboratory

  • Matthew Trantham

    University of Michigan, Univ of Michigan - Ann Arbor

  • Sallee Klein

    University of Michigan, Univ of Michigan - Ann Arbor

  • Carolyn Kuranz

    University of Michigan, Univ of Michigan - Ann Arbor

  • R. Paul Drake

    Univ of Michigan - Ann Arbor, University of Michigan

  • Dov Shvarts

    University of Michigan, University of Michigan; Nuclear Research Center – NEGEV, Israel, Nuclear Research Center-Negev, University of Michigan, University of Michigan, Nuclear Research Center-Negev, Israel, University of Michigan; NRCN, Univ of Michigan - Ann Arbor and Nuclear Research Center-Negev, Israel, University of Michigan, Nuclear Resreach Center-Negev, Israel, Nuclear Research Center-Negev, Israel