X-Ray Diffraction of Diamond on the Double-Shock Hugoniot

ORAL

Abstract

The high-pressure equation of state of carbon is integral to inertial confinement fusion and the modeling of gas giants such as Uranus and Neptune. Numerous studies have investigated the compression and melting curve along the principal Hugoniot, where the liquid--solid coexistence regime exists between 6 and 10 Mbar. Here we explore the secondary Hugoniot of dynamically compressed diamond using velocity interferometry and optical pyrometry. Simultaneous x-ray diffraction measurements are performed to determine the crystal structure and to detect the onset of melting at higher pressures than those accessible by a single shock. This material is based upon work supported by the Department of Energy National Nuclear Security Administration under Award Number DE-NA0003856.

Authors

  • Danae Polsin

    • U. of Rochester's Laboratory for Laser Energetics
    • University of Rochester

  • Mohamed Zaghoo

    • University of Rochester
    • Laboratory for Laser Energetics

  • Gilbert W. Collins

    • Laboratory for Laser Energetics
    • University of Rochester

  • J. Ryan Rygg

    • Laboratory for Laser Energetics
    • University of Rochester

  • Xuchen Gong

    • University of Rochester

  • Grigory Tabak

    • University of Rochester

  • Zaire Sprowal

    • University of Rochester

  • Peter Celliers

    • Lawrence Livermore National Laboratory

  • Dayne Fratanduono

    • Lawrence Livermore National Laboratory

  • Yuan Ping

    • Lawrence Livermore Natl Lab
    • LLNL
    • Lawrence Livermore National Laboratory

  • Jon Eggert

    • Lawrence Livermore National Laboratory

  • Dave Munro

    • Lawrence Livermore National Laboratory

  • Amy Jenei

    • Lawrence Livermore Natl Lab
    • Lawrence Livermore National Laboratory

  • Damien Hicks

    • Swinburne U. of Technology

  • Tom Boehly

    • Laboratory for Laser Energetics