Physical Review Research (Feb 2020)

Melting and refreezing of zirconium observed using ultrafast x-ray diffraction

  • Harry B. Radousky,
  • Michael R. Armstrong,
  • Ryan A. Austin,
  • Elissaios Stavrou,
  • Shaughnessy Brown,
  • Alexander A. Chernov,
  • Arianna E. Gleason,
  • Eduardo Granados,
  • Paulius Grivickas,
  • Nicholas Holtgrewe,
  • Hae Ja Lee,
  • Sergey S. Lobanov,
  • Bob Nagler,
  • Inhyuk Nam,
  • Vitali Prakapenka,
  • Clemens Prescher,
  • Peter Walter,
  • Alexander F. Goncharov,
  • Jonathan L. Belof

DOI
https://doi.org/10.1103/PhysRevResearch.2.013192
Journal volume & issue
Vol. 2, no. 1
p. 013192

Abstract

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Ultrafast (130-fs) x-ray diffraction at the Linac Coherent Light Source has been applied to observe shock melting, which is driven by a rapid (120-ps) laser pulse impinging on a thin (few micrometers) bilayer of aluminum/zirconium. At a pressure of 100 GPa in the aluminum (130 GPa in the zirconium), there is rapid melting of both metals and the recrystallization of zirconium into the bcc β phase. We observe the solidification of the melt starting a few hundred picoseconds following the shock melting, out to 50 ns when the zirconium is fully crystallized into the bcc β phase at a residual temperature of approximately 2000 K. The pressure is obtained directly from the early time x-ray data, whereas the additional information from the x-ray line width and intensity at longer times inform a model of crystal nucleation and growth.