X-Ray Diffraction of Potassium in the High-Pressure Regime

ORAL

Abstract

Due to the high compressibility of alkali metals, they provide a unique window into the high-density behavior of matter at accessible pressures. We are working to quasi-isentropically compress potassium into the terapascal regime to explore the evolution of its ionic and electronic structural complexity with pressure. Theoretical predicts potassium transforms to a double hexagonal-close-packed (dhcp) structure at ~250 GPa.[1] Moreover, the melting curve is seen to drop to a minimum at ~20 GPa[2] then rising precipitously with pressure and without experimental bounds beyond 25 GPa. The high compressibility and low sound speed of potassium make it very difficult to explore these properties at high pressure. Hydrodynamic simulations are used to guide experimental designs to map these physical properties of potassium to pressures approaching 1 TPa. We show preliminary powder diffraction[3] and optical reflectivity measurements for potassium, ramp compressed to 500 GPa.

[1] P. Emma et al., Nat. Phys. 4, 641 (2010).

[2] O. Narygina et al., Phys. Rev. B 84, 054111 (2011).

[3] J. R. Rygg et al., Rev. Sci. Instrum. 83, 113904 (2012).

*This material is based upon work supported by the Department of Energy National Nuclear Security Administration under Award Number DE-NA0001944.

Presenters

  • Xuchen Gong

    • Laboratory for Laser Energetics
    • Lab for Laser Energetics

Authors

  • Xuchen Gong

    • Laboratory for Laser Energetics
    • Lab for Laser Energetics

  • Danae N Polsin

    • Laboratory for Laser Energetics
    • Univ of Rochester
    • Laboratory for Laser Energetics, U. of Rochester

  • James Ryan Rygg

    • Laboratory for Laser Energetics
    • Univ of Rochester
    • Laboratory for Laser Energetics, U. of Rochester
    • University of Rochester
    • University of Rochester, Laboratory for Laser Energetics
    • Univ of Rochester, Univ of Rochester

  • Thomas Boehly

    • Laboratory for Laser Energetics
    • University of Rochester, LLE
    • Lab for Laser Energetics
    • Laboratory for Laser Energetics, U. of Rochester
    • Laboratory for Laser Energetics, Laboratory for Laser Energetics

  • L. E Crandall

    • Univ of Rochester
    • Laboratory for Laser Energetics, U. of Rochester

  • Brian Joseph Henderson

    • Univ of Rochester
    • University of Rochester, LLE
    • Laboratory for Laser Energetics, U. of Rochester

  • S. X. Hu

    • Laboratory for Laser Energetics, U. of Rochester
    • University of Rochester
    • Univ of Rochester
    • Univ of Rochester LLE
    • Laboratory for Laser Energetics
    • Laboratory for Laser Energetics, University of Rochester

  • Margaret Huff

    • Univ of Rochester
    • University of Rochester, Laboratory for Laser Energetics

  • Rahul Saha

    • Lab for Laser Energetics
    • Laboratory for Laser Energetics, U. of Rochester

  • Gilbert W Collins

    • University of Rochester, Departments of Mechanical Engineering, Physics and Astronomy, and Laboratory for Laser Energetics
    • Laboratory for Laser Energetics
    • Univ of Rochester
    • Laboratory for Laser Energetics, U. of Rochester
    • Univ of Rochester, Laboratory for Laser Energetics
    • University of Rochester
    • University of Rochester, Laboratory for Laser Energetics

  • Ray Smith

    • Lawrence Livermore Natl Lab

  • J H Henry Eggert

    • Lawrence Livermore Natl Lab

  • Federica Coppari

    • Lawrence Livermore Natl Lab

  • Amy E Lazicki

    • Lawrence Livermore Natl Lab

  • Malcolm I McMahon

    • Univ of Edinburgh