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

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

13 Scopus citations

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.

Original language	English
Pages (from-to)	2185-2193
Number of pages	9
Journal	JOM
Volume	73
Issue number	7
DOIs	https://doi.org/10.1007/s11837-020-04535-4
State	Published - Jul 2021
Externally published	Yes

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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, vol. 73, no. 7, pp. 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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