Physical Review Research (Sep 2020)

Time-dependent effects in melting and phase change for laser-shocked iron

  • S. White,
  • B. Kettle,
  • J. Vorberger,
  • C. L. S. Lewis,
  • S. H. Glenzer,
  • E. Gamboa,
  • B. Nagler,
  • F. Tavella,
  • H. J. Lee,
  • C. D. Murphy,
  • D. O. Gericke,
  • D. Riley

DOI
https://doi.org/10.1103/PhysRevResearch.2.033366
Journal volume & issue
Vol. 2, no. 3
p. 033366

Abstract

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Using the Linac Coherent Light Source facility at the Stanford Linac Coherent Light Source National Accelerator Laboratory, we have observed x-ray scattering from iron compressed with laser-driven shocks to earth-core-like pressures above 400 GPa. The data show cases where melting is incomplete and we observe hexagonal-close-packed crystal structure at shock compressed densities up to 14.0 g cm^{−3} but no evidence of a double-hexagonal-close-packed crystal. The observation of a crystalline structure at these densities, where shock heating is expected to be in excess of the equilibrium melt temperature, may indicate superheating of the solid. These results are important for equation of state modeling at high strain rates relevant for impact scenarios and laser-driven shock-wave experiments.