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Superheating gold beyond the predicted entropy catastrophe threshold

Author

Listed:
  • Thomas G. White

    (University of Nevada)

  • Travis D. Griffin

    (University of Nevada)

  • Daniel Haden

    (University of Nevada)

  • Hae Ja Lee

    (SLAC National Accelerator Laboratory)

  • Eric Galtier

    (SLAC National Accelerator Laboratory)

  • Eric Cunningham

    (SLAC National Accelerator Laboratory)

  • Dimitri Khaghani

    (SLAC National Accelerator Laboratory)

  • Adrien Descamps

    (SLAC National Accelerator Laboratory
    Queen’s University Belfast)

  • Lennart Wollenweber

    (European XFEL GmbH)

  • Ben Armentrout

    (SLAC National Accelerator Laboratory)

  • Carson Convery

    (SLAC National Accelerator Laboratory
    Columbia University)

  • Karen Appel

    (European XFEL GmbH)

  • Luke B. Fletcher

    (SLAC National Accelerator Laboratory)

  • Sebastian Goede

    (European XFEL GmbH)

  • J. B. Hastings

    (SLAC National Accelerator Laboratory)

  • Jeremy Iratcabal

    (University of Nevada)

  • Emma E. McBride

    (SLAC National Accelerator Laboratory
    Queen’s University Belfast)

  • Jacob Molina

    (University of Nevada
    Princeton University
    Princeton University)

  • Giulio Monaco

    (University of Padova)

  • Landon Morrison

    (University of Nevada
    University of Oxford)

  • Hunter Stramel

    (University of Nevada)

  • Sameen Yunus

    (SLAC National Accelerator Laboratory
    University of California)

  • Ulf Zastrau

    (European XFEL GmbH)

  • Siegfried H. Glenzer

    (SLAC National Accelerator Laboratory)

  • Gianluca Gregori

    (University of Oxford)

  • Dirk O. Gericke

    (University of Warwick)

  • Bob Nagler

    (SLAC National Accelerator Laboratory)

Abstract

In their landmark study1, Fecht and Johnson unveiled a phenomenon that they termed the ‘entropy catastrophe’, a critical point where the entropy of superheated crystals equates to that of their liquid counterparts. This point marks the uppermost stability boundary for solids at temperatures typically around three times their melting point. Despite the theoretical prediction of this ultimate stability threshold, its practical exploration has been prevented by numerous intermediate destabilizing events, colloquially known as a hierarchy of catastrophes2–5, which occur at far lower temperatures. Here we experimentally test this limit under ultrafast heating conditions, directly tracking the lattice temperature by using high-resolution inelastic X-ray scattering. Our gold samples are heated to temperatures over 14 times their melting point while retaining their crystalline structure, far surpassing the predicted threshold and suggesting a substantially higher or potentially no limit for superheating. We point to the inability of our samples to expand on these very short timescales as an important difference from previous estimates. These observations provide insights into the dynamics of melting under extreme conditions.

Suggested Citation

  • Thomas G. White & Travis D. Griffin & Daniel Haden & Hae Ja Lee & Eric Galtier & Eric Cunningham & Dimitri Khaghani & Adrien Descamps & Lennart Wollenweber & Ben Armentrout & Carson Convery & Karen Ap, 2025. "Superheating gold beyond the predicted entropy catastrophe threshold," Nature, Nature, vol. 643(8073), pages 950-954, July.
    • Handle: RePEc:nat:nature:v:643:y:2025:i:8073:d:10.1038_s41586-025-09253-y
    DOI: 10.1038/s41586-025-09253-y
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