Phase transition kinetics of superionic H2O ice phases revealed by Megahertz X-ray free-electron laser-heating experiments

R. J. Husband; H. P. Liermann; J. D. McHardy; R. S. McWilliams; A. F. Goncharov; V. B. Prakapenka; E. Edmund; S. Chariton; Z. Konôpková; C. Strohm; C. Sanchez-Valle; M. Frost; L. Andriambariarijaona; K. Appel; C. Baehtz; O. B. Ball; R. Briggs; J. Buchen; V. Cerantola; J. Choi; A. L. Coleman; H. Cynn; A. Dwivedi; H. Graafsma; H. Hwang; E. Koemets; T. Laurus; Y. Lee; X. Li; H. Marquardt; A. Mondal; M. Nakatsutsumi; S. Ninet; E. Pace; C. Pepin; C. Prescher; S. Stern; J. Sztuk-Dambietz; U. Zastrau; M. I. McMahon

doi:10.1038/s41467-024-52505-0

Phase transition kinetics of superionic H₂O ice phases revealed by Megahertz X-ray free-electron laser-heating experiments

R. J. Husband^*, H. P. Liermann, J. D. McHardy, R. S. McWilliams, A. F. Goncharov, V. B. Prakapenka, E. Edmund, S. Chariton, Z. Konôpková, C. Strohm, C. Sanchez-Valle, M. Frost, L. Andriambariarijaona, K. Appel, C. Baehtz, O. B. Ball, R. Briggs, J. Buchen, V. Cerantola, J. ChoiA. L. Coleman, H. Cynn, A. Dwivedi, H. Graafsma, H. Hwang, E. Koemets, T. Laurus, Y. Lee, X. Li, H. Marquardt, A. Mondal, M. Nakatsutsumi, S. Ninet, E. Pace, C. Pepin, C. Prescher, S. Stern, J. Sztuk-Dambietz, U. Zastrau, M. I. McMahon^*

^*Corresponding author for this work

School of Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

Abstract

H₂O transforms to two forms of superionic (SI) ice at high pressures and temperatures, which contain highly mobile protons within a solid oxygen sublattice. Yet the stability field of both phases remains debated. Here, we present the results of an ultrafast X-ray heating study utilizing MHz pulse trains produced by the European X-ray Free Electron Laser to create high temperature states of H₂O, which were probed using X-ray diffraction during dynamic cooling. We confirm an isostructural transition during heating in the 26-69 GPa range, consistent with the formation of SI-bcc. In contrast to prior work, SI-fcc was observed exclusively above ~50 GPa, despite evidence of melting at lower pressures. The absence of SI-fcc in lower pressure runs is attributed to short heating timescales and the pressure-temperature path induced by the pump-probe heating scheme in which H₂O was heated above its melting temperature before the observation of quenched crystalline states, based on the earlier theoretical prediction that SI-bcc nucleates more readily from the fluid than SI-fcc. Our results may have implications for the stability of SI phases in ice-rich planets, for example during dynamic freezing, where the preferential crystallization of SI-bcc may result in distinct physical properties across mantle ice layers.

Original language	English
Article number	8256
Pages (from-to)	1-13
Number of pages	13
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-52505-0
Publication status	Published - 23 Sept 2024

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Husband, R. J., Liermann, H. P., McHardy, J. D., McWilliams, R. S., Goncharov, A. F., Prakapenka, V. B., Edmund, E., Chariton, S., Konôpková, Z., Strohm, C., Sanchez-Valle, C., Frost, M., Andriambariarijaona, L., Appel, K., Baehtz, C., Ball, O. B., Briggs, R., Buchen, J., Cerantola, V., ... McMahon, M. I. (2024). Phase transition kinetics of superionic H₂O ice phases revealed by Megahertz X-ray free-electron laser-heating experiments. Nature Communications, 15(1), 1-13. Article 8256. https://doi.org/10.1038/s41467-024-52505-0

@article{a854e673044a48309a324bbbd5a1138b,

title = "Phase transition kinetics of superionic H2O ice phases revealed by Megahertz X-ray free-electron laser-heating experiments",

abstract = "H2O transforms to two forms of superionic (SI) ice at high pressures and temperatures, which contain highly mobile protons within a solid oxygen sublattice. Yet the stability field of both phases remains debated. Here, we present the results of an ultrafast X-ray heating study utilizing MHz pulse trains produced by the European X-ray Free Electron Laser to create high temperature states of H2O, which were probed using X-ray diffraction during dynamic cooling. We confirm an isostructural transition during heating in the 26-69 GPa range, consistent with the formation of SI-bcc. In contrast to prior work, SI-fcc was observed exclusively above \textasciitilde{}50 GPa, despite evidence of melting at lower pressures. The absence of SI-fcc in lower pressure runs is attributed to short heating timescales and the pressure-temperature path induced by the pump-probe heating scheme in which H2O was heated above its melting temperature before the observation of quenched crystalline states, based on the earlier theoretical prediction that SI-bcc nucleates more readily from the fluid than SI-fcc. Our results may have implications for the stability of SI phases in ice-rich planets, for example during dynamic freezing, where the preferential crystallization of SI-bcc may result in distinct physical properties across mantle ice layers.",

author = "Husband, \{R. J.\} and Liermann, \{H. P.\} and McHardy, \{J. D.\} and McWilliams, \{R. S.\} and Goncharov, \{A. F.\} and Prakapenka, \{V. B.\} and E. Edmund and S. Chariton and Z. Kon{\^o}pkov{\'a} and C. Strohm and C. Sanchez-Valle and M. Frost and L. Andriambariarijaona and K. Appel and C. Baehtz and Ball, \{O. B.\} and R. Briggs and J. Buchen and V. Cerantola and J. Choi and Coleman, \{A. L.\} and H. Cynn and A. Dwivedi and H. Graafsma and H. Hwang and E. Koemets and T. Laurus and Y. Lee and X. Li and H. Marquardt and A. Mondal and M. Nakatsutsumi and S. Ninet and E. Pace and C. Pepin and C. Prescher and S. Stern and J. Sztuk-Dambietz and U. Zastrau and McMahon, \{M. I.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

month = sep,

day = "23",

doi = "10.1038/s41467-024-52505-0",

language = "English",

volume = "15",

pages = "1--13",

journal = "Nature Communications",

issn = "2041-1723",

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Husband, RJ, Liermann, HP, McHardy, JD, McWilliams, RS, Goncharov, AF, Prakapenka, VB, Edmund, E, Chariton, S, Konôpková, Z, Strohm, C, Sanchez-Valle, C, Frost, M, Andriambariarijaona, L, Appel, K, Baehtz, C, Ball, OB, Briggs, R, Buchen, J, Cerantola, V, Choi, J, Coleman, AL, Cynn, H, Dwivedi, A, Graafsma, H, Hwang, H, Koemets, E, Laurus, T, Lee, Y, Li, X, Marquardt, H, Mondal, A, Nakatsutsumi, M, Ninet, S, Pace, E, Pepin, C, Prescher, C, Stern, S, Sztuk-Dambietz, J, Zastrau, U & McMahon, MI 2024, 'Phase transition kinetics of superionic H₂O ice phases revealed by Megahertz X-ray free-electron laser-heating experiments', Nature Communications, vol. 15, no. 1, 8256, pp. 1-13. https://doi.org/10.1038/s41467-024-52505-0

TY - JOUR

T1 - Phase transition kinetics of superionic H2O ice phases revealed by Megahertz X-ray free-electron laser-heating experiments

AU - Husband, R. J.

AU - Liermann, H. P.

AU - McHardy, J. D.

AU - McWilliams, R. S.

AU - Goncharov, A. F.

AU - Prakapenka, V. B.

AU - Edmund, E.

AU - Chariton, S.

AU - Konôpková, Z.

AU - Strohm, C.

AU - Sanchez-Valle, C.

AU - Frost, M.

AU - Andriambariarijaona, L.

AU - Appel, K.

AU - Baehtz, C.

AU - Ball, O. B.

AU - Briggs, R.

AU - Buchen, J.

AU - Cerantola, V.

AU - Choi, J.

AU - Coleman, A. L.

AU - Cynn, H.

AU - Dwivedi, A.

AU - Graafsma, H.

AU - Hwang, H.

AU - Koemets, E.

AU - Laurus, T.

AU - Lee, Y.

AU - Li, X.

AU - Marquardt, H.

AU - Mondal, A.

AU - Nakatsutsumi, M.

AU - Ninet, S.

AU - Pace, E.

AU - Pepin, C.

AU - Prescher, C.

AU - Stern, S.

AU - Sztuk-Dambietz, J.

AU - Zastrau, U.

AU - McMahon, M. I.

PY - 2024/9/23

Y1 - 2024/9/23

N2 - H2O transforms to two forms of superionic (SI) ice at high pressures and temperatures, which contain highly mobile protons within a solid oxygen sublattice. Yet the stability field of both phases remains debated. Here, we present the results of an ultrafast X-ray heating study utilizing MHz pulse trains produced by the European X-ray Free Electron Laser to create high temperature states of H2O, which were probed using X-ray diffraction during dynamic cooling. We confirm an isostructural transition during heating in the 26-69 GPa range, consistent with the formation of SI-bcc. In contrast to prior work, SI-fcc was observed exclusively above ~50 GPa, despite evidence of melting at lower pressures. The absence of SI-fcc in lower pressure runs is attributed to short heating timescales and the pressure-temperature path induced by the pump-probe heating scheme in which H2O was heated above its melting temperature before the observation of quenched crystalline states, based on the earlier theoretical prediction that SI-bcc nucleates more readily from the fluid than SI-fcc. Our results may have implications for the stability of SI phases in ice-rich planets, for example during dynamic freezing, where the preferential crystallization of SI-bcc may result in distinct physical properties across mantle ice layers.

AB - H2O transforms to two forms of superionic (SI) ice at high pressures and temperatures, which contain highly mobile protons within a solid oxygen sublattice. Yet the stability field of both phases remains debated. Here, we present the results of an ultrafast X-ray heating study utilizing MHz pulse trains produced by the European X-ray Free Electron Laser to create high temperature states of H2O, which were probed using X-ray diffraction during dynamic cooling. We confirm an isostructural transition during heating in the 26-69 GPa range, consistent with the formation of SI-bcc. In contrast to prior work, SI-fcc was observed exclusively above ~50 GPa, despite evidence of melting at lower pressures. The absence of SI-fcc in lower pressure runs is attributed to short heating timescales and the pressure-temperature path induced by the pump-probe heating scheme in which H2O was heated above its melting temperature before the observation of quenched crystalline states, based on the earlier theoretical prediction that SI-bcc nucleates more readily from the fluid than SI-fcc. Our results may have implications for the stability of SI phases in ice-rich planets, for example during dynamic freezing, where the preferential crystallization of SI-bcc may result in distinct physical properties across mantle ice layers.

UR - https://www.scopus.com/pages/publications/85204927740

U2 - 10.1038/s41467-024-52505-0

DO - 10.1038/s41467-024-52505-0

M3 - Article

C2 - 39313509

AN - SCOPUS:85204927740

SN - 2041-1723

VL - 15

SP - 1

EP - 13

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 8256

ER -

Phase transition kinetics of superionic H₂O ice phases revealed by Megahertz X-ray free-electron laser-heating experiments

Abstract

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Dynamic States in Diamond Anvil Cells

New Emergent Quantum States of Matter at High Pressure

Frontier Experiments in Dynamic Extreme Conditions: The Case for Light Elements

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Phase transition kinetics of superionic H2O ice phases revealed by Megahertz X-ray free-electron laser-heating experiments

Abstract

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Dynamic States in Diamond Anvil Cells

New Emergent Quantum States of Matter at High Pressure

Frontier Experiments in Dynamic Extreme Conditions: The Case for Light Elements

Cite this

Phase transition kinetics of superionic H₂O ice phases revealed by Megahertz X-ray free-electron laser-heating experiments