2D Rad-MHD Model Assessment of Designs for Multiple-Shell Gas Nozzles for Z

POSTER

Abstract

AASC is designing multiple-shell gas puff loads for Z. Here we assess the influence of the loads initial gas distribution on its K-shell yield performance. Emphasis is placed on designing an optimal central jet initial gas distribution, since it is believed to have a controlling effect on pinch stability, pinch conditions, and radiation physics [1]. We are looking at distributions that optimize total Ar K-shell emission and high energy ($>$10 KeV) continuum radiation. This investigation is performed with the Mach2 MHD code with non-LTE kinetics and ray trace based radiation transport. \\[4pt] [1] H. Sze, \textit{et al}., PRL, \textbf{95}, 105001 (2005).

*Work supported by DOE/NNSA, Sandia is a multi-program laboratory operated by Sandia Corp., a Lockheed Martin Company, for the United States DOE's National Nuclear Security Admin. under contract DE-AC04-94AL85000.

Authors

  • J. Thornhill

    • Plasma Physics Division, Naval Research Laboraory

  • J. Giuliani

    • Plasma Physics Division, Naval Research Laboraory

  • A. Velikovich

    • Plasma Physics Division, Naval Research Laboraory

  • J. Apruzese

    • Plasma Physics Division, Naval Research Laboraory

  • Y. Chong

    • Plasma Physics Division, Naval Research Laboraory

  • J. Davis

    • Plasma Physics Division, Naval Research Laboraory

  • A. Dasgupta

    • Plasma Physics Division, Naval Research Laboraory

  • R. Clark

    • Berkeley Scholars, Inc.

  • B. Jones

    • Sandia National Laboratory

  • C. Coverdale

    • Sandia National Laboratory

  • D. Ampleford

    • Sandia National Laboratory

  • C. Jennings

    • Sandia National Laboratory

  • M. Cuneo

    • Sandia National Laboratory

  • E. Waisman

    • Sandia National Laboratory

  • M. Krishnan

    • Alameda Applied Sciences Corp.

  • P. Coleman

    • consultant