Observation of Fundamental Mechanisms in Compression-Induced Phase Transformations Using Ultrafast X-ray Diffraction

Michael R. Armstrong; Harry B. Radousky; Ryan A. Austin; Elissaios Stavrou; Hongxiang Zong; Graeme J. Ackland; Shaughnessy Brown; Jonathan C. Crowhurst; Arianna E. Gleason; Eduardo Granados; Paulius Grivickas; Nicholas Holtgrewe; Hae Ja Lee; Tian T. Li; Sergey Lobanov; Joseph T. McKeown; Bob Nagler; Inhyuk Nam; Art J. Nelson; Vitali Prakapenka; Clemens Prescher; John D. Roehling; Nick E. Teslich; Peter Walter; Alexander F. Goncharov; Jonathan L. Belof

doi:10.1007/s11837-020-04535-4

Observation of Fundamental Mechanisms in Compression-Induced Phase Transformations Using Ultrafast X-ray Diffraction

Michael R. Armstrong
, Harry B. Radousky
, Ryan A. Austin
, Elissaios Stavrou
, Hongxiang Zong
, Graeme J. Ackland
, Shaughnessy Brown
, Jonathan C. Crowhurst
, Arianna E. Gleason
, Eduardo Granados
, Paulius Grivickas
, Nicholas Holtgrewe
, Hae Ja Lee
, Tian T. Li
, Sergey Lobanov
, Joseph T. McKeown
, Bob Nagler
, Inhyuk Nam
, Art J. Nelson
, Vitali Prakapenka

Clemens Prescher, John D. Roehling, Nick E. Teslich, Peter Walter, Alexander F. Goncharov, Jonathan L. Belof

Chem./Materials Science Directorate
University of Edinburgh
SLAC National Accelerator Laboratory
Computational Earth Science, Earth and Environmental Sciences Division, Los Alamos National Laboratory
Carnegie Institution of Washington
The University of Chicago
University of Cologne

科研成果: 期刊稿件 › 文章 › 同行评审

13 引用（Scopus）

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As theoretically hypothesized for several decades in group IV transition metals, we have discovered a dynamically stabilized body-centered cubic (bcc) intermediate state in Zr under uniaxial loading at sub-nanosecond timescales. Under ultrafast shock wave compression, rather than the transformation from α-Zr to the more disordered hex-3 equilibrium ω-Zr phase, in its place we find the formation of a previously unobserved nonequilibrium bcc metastable intermediate. We probe the compression-induced phase transition pathway in zirconium using time-resolved sub-picosecond x-ray diffraction analysis at the Linac Coherent Light Source. We also present molecular dynamics simulations using a potential derived from first-principles methods which independently predict this intermediate phase under ultrafast shock conditions. In contrast with experiments on longer timescale (> 10 ns) where the phase diagram alone is an adequate predictor of the crystalline structure of a material, our recent study highlights the importance of metastability and time dependence in the kinetics of phase transformations.

源语言	英语
页（从-至）	2185-2193
页数	9
期刊	JOM
卷	73
期	7
DOI	https://doi.org/10.1007/s11837-020-04535-4
出版状态	已出版 - 7月 2021
已对外发布	是

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Armstrong, M. R., Radousky, H. B., Austin, R. A., Stavrou, E., Zong, H., Ackland, G. J., Brown, S., Crowhurst, J. C., Gleason, A. E., Granados, E., Grivickas, P., Holtgrewe, N., Lee, H. J., Li, T. T., Lobanov, S., McKeown, J. T., Nagler, B., Nam, I., Nelson, A. J., ... Belof, J. L. (2021). Observation of Fundamental Mechanisms in Compression-Induced Phase Transformations Using Ultrafast X-ray Diffraction. JOM, 73(7), 2185-2193. https://doi.org/10.1007/s11837-020-04535-4

@article{2f56e6bba68a4b1cbb402740375850be,

title = "Observation of Fundamental Mechanisms in Compression-Induced Phase Transformations Using Ultrafast X-ray Diffraction",

abstract = "As theoretically hypothesized for several decades in group IV transition metals, we have discovered a dynamically stabilized body-centered cubic (bcc) intermediate state in Zr under uniaxial loading at sub-nanosecond timescales. Under ultrafast shock wave compression, rather than the transformation from α-Zr to the more disordered hex-3 equilibrium ω-Zr phase, in its place we find the formation of a previously unobserved nonequilibrium bcc metastable intermediate. We probe the compression-induced phase transition pathway in zirconium using time-resolved sub-picosecond x-ray diffraction analysis at the Linac Coherent Light Source. We also present molecular dynamics simulations using a potential derived from first-principles methods which independently predict this intermediate phase under ultrafast shock conditions. In contrast with experiments on longer timescale (> 10 ns) where the phase diagram alone is an adequate predictor of the crystalline structure of a material, our recent study highlights the importance of metastability and time dependence in the kinetics of phase transformations.",

author = "Armstrong, \{Michael R.\} and Radousky, \{Harry B.\} and Austin, \{Ryan A.\} and Elissaios Stavrou and Hongxiang Zong and Ackland, \{Graeme J.\} and Shaughnessy Brown and Crowhurst, \{Jonathan C.\} and Gleason, \{Arianna E.\} and Eduardo Granados and Paulius Grivickas and Nicholas Holtgrewe and Lee, \{Hae Ja\} and Li, \{Tian T.\} and Sergey Lobanov and McKeown, \{Joseph T.\} and Bob Nagler and Inhyuk Nam and Nelson, \{Art J.\} and Vitali Prakapenka and Clemens Prescher and Roehling, \{John D.\} and Teslich, \{Nick E.\} and Peter Walter and Goncharov, \{Alexander F.\} and Belof, \{Jonathan L.\}",

note = "Publisher Copyright: {\textcopyright} 2021, This is a U.S. government work and not under copyright protection in the U.S.; foreign copyright protection may apply.",

year = "2021",

month = jul,

doi = "10.1007/s11837-020-04535-4",

language = "英语",

volume = "73",

pages = "2185--2193",

journal = "JOM",

issn = "1047-4838",

publisher = "Minerals, Metals and Materials Society",

number = "7",

}

Armstrong, MR, Radousky, HB, Austin, RA, Stavrou, E, Zong, H, Ackland, GJ, Brown, S, Crowhurst, JC, Gleason, AE, Granados, E, Grivickas, P, Holtgrewe, N, Lee, HJ, Li, TT, Lobanov, S, McKeown, JT, Nagler, B, Nam, I, Nelson, AJ, Prakapenka, V, Prescher, C, Roehling, JD, Teslich, NE, Walter, P, Goncharov, AF & Belof, JL 2021, 'Observation of Fundamental Mechanisms in Compression-Induced Phase Transformations Using Ultrafast X-ray Diffraction', JOM, 卷 73, 号码 7, 页码 2185-2193. https://doi.org/10.1007/s11837-020-04535-4

TY - JOUR

T1 - Observation of Fundamental Mechanisms in Compression-Induced Phase Transformations Using Ultrafast X-ray Diffraction

AU - Armstrong, Michael R.

AU - Radousky, Harry B.

AU - Austin, Ryan A.

AU - Stavrou, Elissaios

AU - Zong, Hongxiang

AU - Ackland, Graeme J.

AU - Brown, Shaughnessy

AU - Crowhurst, Jonathan C.

AU - Gleason, Arianna E.

AU - Granados, Eduardo

AU - Grivickas, Paulius

AU - Holtgrewe, Nicholas

AU - Lee, Hae Ja

AU - Li, Tian T.

AU - Lobanov, Sergey

AU - McKeown, Joseph T.

AU - Nagler, Bob

AU - Nam, Inhyuk

AU - Nelson, Art J.

AU - Prakapenka, Vitali

AU - Prescher, Clemens

AU - Roehling, John D.

AU - Teslich, Nick E.

AU - Walter, Peter

AU - Goncharov, Alexander F.

AU - Belof, Jonathan L.

PY - 2021/7

Y1 - 2021/7

N2 - As theoretically hypothesized for several decades in group IV transition metals, we have discovered a dynamically stabilized body-centered cubic (bcc) intermediate state in Zr under uniaxial loading at sub-nanosecond timescales. Under ultrafast shock wave compression, rather than the transformation from α-Zr to the more disordered hex-3 equilibrium ω-Zr phase, in its place we find the formation of a previously unobserved nonequilibrium bcc metastable intermediate. We probe the compression-induced phase transition pathway in zirconium using time-resolved sub-picosecond x-ray diffraction analysis at the Linac Coherent Light Source. We also present molecular dynamics simulations using a potential derived from first-principles methods which independently predict this intermediate phase under ultrafast shock conditions. In contrast with experiments on longer timescale (> 10 ns) where the phase diagram alone is an adequate predictor of the crystalline structure of a material, our recent study highlights the importance of metastability and time dependence in the kinetics of phase transformations.

AB - As theoretically hypothesized for several decades in group IV transition metals, we have discovered a dynamically stabilized body-centered cubic (bcc) intermediate state in Zr under uniaxial loading at sub-nanosecond timescales. Under ultrafast shock wave compression, rather than the transformation from α-Zr to the more disordered hex-3 equilibrium ω-Zr phase, in its place we find the formation of a previously unobserved nonequilibrium bcc metastable intermediate. We probe the compression-induced phase transition pathway in zirconium using time-resolved sub-picosecond x-ray diffraction analysis at the Linac Coherent Light Source. We also present molecular dynamics simulations using a potential derived from first-principles methods which independently predict this intermediate phase under ultrafast shock conditions. In contrast with experiments on longer timescale (> 10 ns) where the phase diagram alone is an adequate predictor of the crystalline structure of a material, our recent study highlights the importance of metastability and time dependence in the kinetics of phase transformations.

UR - https://www.scopus.com/pages/publications/85099400283

U2 - 10.1007/s11837-020-04535-4

DO - 10.1007/s11837-020-04535-4

M3 - 文章

AN - SCOPUS:85099400283

SN - 1047-4838

VL - 73

SP - 2185

EP - 2193

JO - JOM

JF - JOM

IS - 7

ER -

Observation of Fundamental Mechanisms in Compression-Induced Phase Transformations Using Ultrafast X-ray Diffraction

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