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Microstructure and crystal order during freezing of supercooled water drops

Author

Listed:
  • Armin Kalita

    (Rutgers University–Newark)

  • Maximillian Mrozek-McCourt

    (Rutgers University–Newark
    Lehigh University)

  • Thomas F. Kaldawi

    (Rutgers University–Newark
    University of Rochester)

  • Philip R. Willmott

    (SLAC National Accelerator Laboratory
    Paul Scherrer Institute)

  • N. Duane Loh

    (SLAC National Accelerator Laboratory
    National University of Singapore
    National University of Singapore)

  • Sebastian Marte

    (Rutgers University–Newark)

  • Raymond G. Sierra

    (SLAC National Accelerator Laboratory
    Linac Coherent Light Source, SLAC National Accelerator Laboratory)

  • Hartawan Laksmono

    (SLAC National Accelerator Laboratory
    KLA-Tencor)

  • Jason E. Koglin

    (SLAC National Accelerator Laboratory
    Los Alamos National Laboratory)

  • Matt J. Hayes

    (SLAC National Accelerator Laboratory)

  • Robert H. Paul

    (SLAC National Accelerator Laboratory)

  • Serge A. H. Guillet

    (SLAC National Accelerator Laboratory)

  • Andrew L. Aquila

    (SLAC National Accelerator Laboratory)

  • Mengning Liang

    (SLAC National Accelerator Laboratory)

  • Sébastien Boutet

    (SLAC National Accelerator Laboratory)

  • Claudiu A. Stan

    (Rutgers University–Newark
    SLAC National Accelerator Laboratory)

Abstract

Supercooled water droplets are widely used to study supercooled water1,2, ice nucleation3–5 and droplet freezing6–11. Their freezing in the atmosphere affects the dynamics and climate feedback of clouds12,13 and can accelerate cloud freezing through secondary ice production14–17. Droplet freezing occurs at several timescales and length scales14,18 and is sufficiently stochastic to make it unlikely that two frozen drops are identical. Here we use optical microscopy and X-ray laser diffraction to investigate the freezing of tens of thousands of water microdrops in vacuum after homogeneous ice nucleation around 234–235 K. On the basis of drop images, we developed a seven-stage model of freezing and used it to time the diffraction data. Diffraction from ice crystals showed that long-range crystalline order formed in less than 1 ms after freezing, whereas diffraction from the remaining liquid became similar to that from quasi-liquid layers on premelted ice19,20. The ice had a strained hexagonal crystal structure just after freezing, which is an early metastable state that probably precedes the formation of ice with stacking defects8,9,18. The techniques reported here could help determine the dynamics of freezing in other conditions, such as drop freezing in clouds, or help understand rapid solidification in other materials.

Suggested Citation

  • Armin Kalita & Maximillian Mrozek-McCourt & Thomas F. Kaldawi & Philip R. Willmott & N. Duane Loh & Sebastian Marte & Raymond G. Sierra & Hartawan Laksmono & Jason E. Koglin & Matt J. Hayes & Robert H, 2023. "Microstructure and crystal order during freezing of supercooled water drops," Nature, Nature, vol. 620(7974), pages 557-561, August.
    • Handle: RePEc:nat:nature:v:620:y:2023:i:7974:d:10.1038_s41586-023-06283-2
    DOI: 10.1038/s41586-023-06283-2
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    Cited by:

    1. Xiao Yan & Samuel C. Y. Au & Sui Cheong Chan & Ying Lung Chan & Ngai Chun Leung & Wa Yat Wu & Dixon T. Sin & Guanlei Zhao & Casper H. Y. Chung & Mei Mei & Yinchuang Yang & Huihe Qiu & Shuhuai Yao, 2024. "Unraveling the role of vaporization momentum in self-jumping dynamics of freezing supercooled droplets at reduced pressures," Nature Communications, Nature, vol. 15(1), pages 1-10, December.

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