Time-sequenced X-ray observation and modeling of a thermal explosion

ORAL

Abstract

The evolution of a thermally-initiated explosion is studied using a multiple-image x-ray system. PBX-9501 is used in this work, enabling direct comparison to recently-published data obtained with proton radiography. For each observed explosion, four x-ray images of the explosive are obtained, each image spaced by tens of microseconds. The multi-physics code, ALE3D, is used to model the pre-ignition thermal profile and post-ignition deflagration of the solid explosive. The model incorporates chemical decomposition, thermal transport, and implicit hydrodynamics to enable accurate prediction of ignition time and temperature. A convective burn model is also implemented in ALE3D to simulate the post-ignition deflagration of thermally-damaged solid energetic materials.

*This work was performed under the auspices of the U.S. Dept. of Energy Lawrence Livermore National Laboratory under Contract DE-AC52-07NA27344.

Authors

  • Joseph Tringe

    • Lawrence Livermore National Laboratory

  • J.D. Molitoris

    • Lawrence Livermore National Laboratory
    • Energetic Materials Center, Lawrence Livermore National Laboratory

  • Laura Smilowitz

    • Chemistry Division, LANL
    • Los Alamos National Laboratory

  • James Kercher

    • Lawrence Livermore National Laboratory

  • Keo Springer

    • Lawrence Livermore National Laboratory

  • Brian Henson

    • Los Alamos National Laboratory
    • Chemistry Division, LANL

  • Daniel Greenwood

    • Lawrence Livermore National Laboratory

  • Raul Garza

    • Lawrence Livermore National Laboratory

  • Bradley Wong

    • Lawrence Livermore National Laboratory

  • Jan Batteux

    • Lawrence Livermore National Laboratory

  • Jon Maienschein

    • Lawrence Livermore National Lab
    • Lawrence Livermore National Laboratory