X-ray thermal diffuse scattering as a texture-robust temperature diagnostic for dynamically compressed solids

P. G. Heighway; D. J. Peake; T. Stevens; J. S. Wark; B. Albertazzi; S. J. Ali; L. Antonelli; M. R. Armstrong; C. Baehtz; O. B. Ball; S. Banerjee; A. B. Belonoshko; C. A. Bolme; V. Bouffetier; R. Briggs; K. Buakor; T. Butcher; S. Di Dio Cafiso; V. Cerantola; J. Chantel; A. Di Cicco; A. L. Coleman; J. Collier; G. Collins; A. J. Comley; F. Coppari; T. E. Cowan; G. Cristoforetti; H. Cynn; A. Descamps; F. Dorchies; M. J. Duff; A. Dwivedi; C. Edwards; J. H. Eggert; D. Errandonea; G. Fiquet; E. Galtier; A. Laso Garcia; H. Ginestet; L. Gizzi; A. Gleason; S. Goede; J. M. Gonzalez; M. G. Gorman; M. Harmand; N. J. Hartley; C. Hernandez-Gomez; A. Higginbotham; H. Höppner; O. S. Humphries; R. J. Husband; T. M. Hutchinson; H. Hwang; D. A. Keen; J. Kim; P. Koester; Z. Konopkova; D. Kraus; A. Krygier; L. Labate; A. E. Lazicki; Y. Lee; H. P. Liermann; P. Mason; M. Masruri; B. Massani; E. E. McBride; C. McGuire; J. D. McHardy; D. McGonegle; R. S. McWilliams; S. Merkel; G. Morard; B. Nagler; M. Nakatsutsumi; K. Nguyen-Cong; A. M. Norton; I. I. Oleynik; C. Otzen; N. Ozaki; S. Pandolfi; A. Pelka; K. A. Pereira; J. P. Phillips; C. Prescher; T. Preston; L. Randolph; D. Ranjan; A. Ravasio; J. Rips; D. Santamaria-Perez; D. J. Savage; M. Schoelmerich; J. P. Schwinkendorf; S. Singh; J. Smith; R. F. Smith; A. Sollier; J. Spear; C. Spindloe; M. Stevenson; C. Strohm; T. A. Suer; M. Tang; M. Toncian; T. Toncian; S. J. Tracy; A. Trapananti; T. Tschentscher; M. Tyldesley; C. E. Vennari; T. Vinci; S. C. Vogel; T. J. Volz; J. Vorberger; J. T. Willman; L. Wollenweber; U. Zastrau; E. Brambrink; K. Appel; M. I. McMahon

doi:10.1063/5.0295250

X-ray thermal diffuse scattering as a texture-robust temperature diagnostic for dynamically compressed solids

P. G. Heighway
, D. J. Peake
, T. Stevens
, J. S. Wark
, B. Albertazzi
, S. J. Ali
, L. Antonelli
, M. R. Armstrong
, C. Baehtz
, O. B. Ball
, S. Banerjee
, A. B. Belonoshko
, C. A. Bolme
, V. Bouffetier
, R. Briggs
, K. Buakor
, T. Butcher
, S. Di Dio Cafiso
, V. Cerantola
, J. Chantel

A. Di Cicco, A. L. Coleman, J. Collier, G. Collins, A. J. Comley, F. Coppari, T. E. Cowan, G. Cristoforetti, H. Cynn, A. Descamps, F. Dorchies, M. J. Duff, A. Dwivedi, C. Edwards, J. H. Eggert, D. Errandonea, G. Fiquet, E. Galtier, A. Laso Garcia, H. Ginestet, L. Gizzi, A. Gleason, S. Goede, J. M. Gonzalez, M. G. Gorman, M. Harmand, N. J. Hartley, C. Hernandez-Gomez, A. Higginbotham, H. Höppner, O. S. Humphries, R. J. Husband, T. M. Hutchinson, H. Hwang, D. A. Keen, J. Kim, P. Koester, Z. Konopkova, D. Kraus, A. Krygier, L. Labate, A. E. Lazicki, Y. Lee, H. P. Liermann, P. Mason, M. Masruri, B. Massani, E. E. McBride, C. McGuire, J. D. McHardy, D. McGonegle, R. S. McWilliams, S. Merkel, G. Morard, B. Nagler, M. Nakatsutsumi, K. Nguyen-Cong, A. M. Norton, I. I. Oleynik, C. Otzen, N. Ozaki, S. Pandolfi, A. Pelka, K. A. Pereira, J. P. Phillips, C. Prescher, T. Preston, L. Randolph, D. Ranjan, A. Ravasio, J. Rips, D. Santamaria-Perez, D. J. Savage, M. Schoelmerich, J. P. Schwinkendorf, S. Singh, J. Smith, R. F. Smith, A. Sollier, J. Spear, C. Spindloe, M. Stevenson, C. Strohm, T. A. Suer, M. Tang, M. Toncian, T. Toncian, S. J. Tracy, A. Trapananti, T. Tschentscher, M. Tyldesley, C. E. Vennari, T. Vinci, S. C. Vogel, T. J. Volz, J. Vorberger, J. T. Willman, L. Wollenweber, U. Zastrau, E. Brambrink, K. Appel, M. I. McMahon

University of Oxford
Lawrence Livermore National Laboratory
University of York
Institute of Radiooncology - OncoRay
University of Edinburgh
Central Laser Facility
Nanjing University
MST-8, Los Alamos National Laboratory
European XFEL GmbH
University of Milano-Bicocca
Université de Lille
University of Camerino
University of Rochester Laboratory for Laser Energetics
AWE - Aldermaston
LENS
Queen's University of Belfast
CELIA, Université Bordeaux i, UMR 5107 (CNRS, Bordeaux 1, CEA)
University of Valencia
Sorbonne Université
Stanford Linear Accelerator Center
University of South Florida, Tampa
Arts et Métiers ParisTech
c/o DESY
Harwell Campus
Hanyang University
Universität Rostock
Yonsei University
Université Joseph Fourier - Grenoble
University of Freiburg
Osaka University
UMass Amherst
Paul Scherrer Institut
CEA/UVSQ/CNRS
Université Paris-Saclay
Carnegie Science
LULI

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We present a model of x-ray thermal diffuse scattering (TDS) from a cubic polycrystal with an arbitrary crystallographic texture, based on the classic approach of Warren [B. E. Warren, Acta Crystallogr. 6, 803 (1953)]. We compare the predictions of our model with femtosecond x-ray diffraction patterns gathered from ambient and dynamically compressed rolled copper foils obtained at the High Energy Density instrument of the European X-Ray Free-Electron Laser facility and find that the texture-aware TDS model yields more accurate results than does the conventional powder model owed to Warren. Nevertheless, we further show: with sufficient angular detector coverage, the TDS signal is largely unchanged by sample orientation and in all cases strongly resembles the signal from a perfectly random powder; shot-to-shot fluctuations in the TDS signal resulting from grain-sampling statistics are at the percent level, in stark contrast to the fluctuations in the Bragg-peak intensities (which are over an order of magnitude greater); and TDS is largely unchanged even following texture evolution caused by compression-induced plastic deformation. We conclude that TDS is robust against texture variation, making it a flexible temperature diagnostic applicable just as well to off-the-shelf commercial foils as to ideal powders.

langue originale	Anglais
Numéro d'article	155903
journal	Journal of Applied Physics
Volume	138
Numéro de publication	15
Les DOIs	https://doi.org/10.1063/5.0295250
état	Publié - 21 oct. 2025

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10.1063/5.0295250

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Heighway, P. G., Peake, D. J., Stevens, T., Wark, J. S., Albertazzi, B., Ali, S. J., Antonelli, L., Armstrong, M. R., Baehtz, C., Ball, O. B., Banerjee, S., Belonoshko, A. B., Bolme, C. A., Bouffetier, V., Briggs, R., Buakor, K., Butcher, T., Di Dio Cafiso, S., Cerantola, V., ... McMahon, M. I. (2025). X-ray thermal diffuse scattering as a texture-robust temperature diagnostic for dynamically compressed solids. Journal of Applied Physics, 138(15), Article 155903. https://doi.org/10.1063/5.0295250

@article{df4ae5bbaddc46ef80a240391c3d927b,

title = "X-ray thermal diffuse scattering as a texture-robust temperature diagnostic for dynamically compressed solids",

abstract = "We present a model of x-ray thermal diffuse scattering (TDS) from a cubic polycrystal with an arbitrary crystallographic texture, based on the classic approach of Warren [B. E. Warren, Acta Crystallogr. 6, 803 (1953)]. We compare the predictions of our model with femtosecond x-ray diffraction patterns gathered from ambient and dynamically compressed rolled copper foils obtained at the High Energy Density instrument of the European X-Ray Free-Electron Laser facility and find that the texture-aware TDS model yields more accurate results than does the conventional powder model owed to Warren. Nevertheless, we further show: with sufficient angular detector coverage, the TDS signal is largely unchanged by sample orientation and in all cases strongly resembles the signal from a perfectly random powder; shot-to-shot fluctuations in the TDS signal resulting from grain-sampling statistics are at the percent level, in stark contrast to the fluctuations in the Bragg-peak intensities (which are over an order of magnitude greater); and TDS is largely unchanged even following texture evolution caused by compression-induced plastic deformation. We conclude that TDS is robust against texture variation, making it a flexible temperature diagnostic applicable just as well to off-the-shelf commercial foils as to ideal powders.",

author = "Heighway, \{P. G.\} and Peake, \{D. J.\} and T. Stevens and Wark, \{J. S.\} and B. Albertazzi and Ali, \{S. J.\} and L. Antonelli and Armstrong, \{M. R.\} and C. Baehtz and Ball, \{O. B.\} and S. Banerjee and Belonoshko, \{A. B.\} and Bolme, \{C. A.\} and V. Bouffetier and R. Briggs and K. Buakor and T. Butcher and \{Di Dio Cafiso\}, S. and V. Cerantola and J. Chantel and \{Di Cicco\}, A. and Coleman, \{A. L.\} and J. Collier and G. Collins and Comley, \{A. J.\} and F. Coppari and Cowan, \{T. E.\} and G. Cristoforetti and H. Cynn and A. Descamps and F. Dorchies and Duff, \{M. J.\} and A. Dwivedi and C. Edwards and Eggert, \{J. H.\} and D. Errandonea and G. Fiquet and E. Galtier and \{Laso Garcia\}, A. and H. Ginestet and L. Gizzi and A. Gleason and S. Goede and Gonzalez, \{J. M.\} and Gorman, \{M. G.\} and M. Harmand and Hartley, \{N. J.\} and C. Hernandez-Gomez and A. Higginbotham and H. H{\"o}ppner and Humphries, \{O. S.\} and Husband, \{R. J.\} and Hutchinson, \{T. M.\} and H. Hwang and Keen, \{D. A.\} and J. Kim and P. Koester and Z. Konopkova and D. Kraus and A. Krygier and L. Labate and Lazicki, \{A. E.\} and Y. Lee and Liermann, \{H. P.\} and P. Mason and M. Masruri and B. Massani and McBride, \{E. E.\} and C. McGuire and McHardy, \{J. D.\} and D. McGonegle and McWilliams, \{R. S.\} and S. Merkel and G. Morard and B. Nagler and M. Nakatsutsumi and K. Nguyen-Cong and Norton, \{A. M.\} and Oleynik, \{I. I.\} and C. Otzen and N. Ozaki and S. Pandolfi and A. Pelka and Pereira, \{K. A.\} and Phillips, \{J. P.\} and C. Prescher and T. Preston and L. Randolph and D. Ranjan and A. Ravasio and J. Rips and D. Santamaria-Perez and Savage, \{D. J.\} and M. Schoelmerich and Schwinkendorf, \{J. P.\} and S. Singh and J. Smith and Smith, \{R. F.\} and A. Sollier and J. Spear and C. Spindloe and M. Stevenson and C. Strohm and Suer, \{T. A.\} and M. Tang and M. Toncian and T. Toncian and Tracy, \{S. J.\} and A. Trapananti and T. Tschentscher and M. Tyldesley and Vennari, \{C. E.\} and T. Vinci and Vogel, \{S. C.\} and Volz, \{T. J.\} and J. Vorberger and Willman, \{J. T.\} and L. Wollenweber and U. Zastrau and E. Brambrink and K. Appel and McMahon, \{M. I.\}",

note = "Publisher Copyright: {\textcopyright} 2025 Author(s).",

year = "2025",

month = oct,

day = "21",

doi = "10.1063/5.0295250",

language = "English",

volume = "138",

journal = "Journal of Applied Physics",

issn = "0021-8979",

number = "15",

}

Heighway, PG, Peake, DJ, Stevens, T, Wark, JS, Albertazzi, B, Ali, SJ, Antonelli, L, Armstrong, MR, Baehtz, C, Ball, OB, Banerjee, S, Belonoshko, AB, Bolme, CA, Bouffetier, V, Briggs, R, Buakor, K, Butcher, T, Di Dio Cafiso, S, Cerantola, V, Chantel, J, Di Cicco, A, Coleman, AL, Collier, J, Collins, G, Comley, AJ, Coppari, F, Cowan, TE, Cristoforetti, G, Cynn, H, Descamps, A, Dorchies, F, Duff, MJ, Dwivedi, A, Edwards, C, Eggert, JH, Errandonea, D, Fiquet, G, Galtier, E, Laso Garcia, A, Ginestet, H, Gizzi, L, Gleason, A, Goede, S, Gonzalez, JM, Gorman, MG, Harmand, M, Hartley, NJ, Hernandez-Gomez, C, Higginbotham, A, Höppner, H, Humphries, OS, Husband, RJ, Hutchinson, TM, Hwang, H, Keen, DA, Kim, J, Koester, P, Konopkova, Z, Kraus, D, Krygier, A, Labate, L, Lazicki, AE, Lee, Y, Liermann, HP, Mason, P, Masruri, M, Massani, B, McBride, EE, McGuire, C, McHardy, JD, McGonegle, D, McWilliams, RS, Merkel, S, Morard, G, Nagler, B, Nakatsutsumi, M, Nguyen-Cong, K, Norton, AM, Oleynik, II, Otzen, C, Ozaki, N, Pandolfi, S, Pelka, A, Pereira, KA, Phillips, JP, Prescher, C, Preston, T, Randolph, L, Ranjan, D, Ravasio, A, Rips, J, Santamaria-Perez, D, Savage, DJ, Schoelmerich, M, Schwinkendorf, JP, Singh, S, Smith, J, Smith, RF, Sollier, A, Spear, J, Spindloe, C, Stevenson, M, Strohm, C, Suer, TA, Tang, M, Toncian, M, Toncian, T, Tracy, SJ, Trapananti, A, Tschentscher, T, Tyldesley, M, Vennari, CE, Vinci, T, Vogel, SC, Volz, TJ, Vorberger, J, Willman, JT, Wollenweber, L, Zastrau, U, Brambrink, E, Appel, K & McMahon, MI 2025, 'X-ray thermal diffuse scattering as a texture-robust temperature diagnostic for dynamically compressed solids', Journal of Applied Physics, VOL. 138, Numéro 15, 155903. https://doi.org/10.1063/5.0295250

TY - JOUR

T1 - X-ray thermal diffuse scattering as a texture-robust temperature diagnostic for dynamically compressed solids

AU - Heighway, P. G.

AU - Peake, D. J.

AU - Stevens, T.

AU - Wark, J. S.

AU - Albertazzi, B.

AU - Ali, S. J.

AU - Antonelli, L.

AU - Armstrong, M. R.

AU - Baehtz, C.

AU - Ball, O. B.

AU - Banerjee, S.

AU - Belonoshko, A. B.

AU - Bolme, C. A.

AU - Bouffetier, V.

AU - Briggs, R.

AU - Buakor, K.

AU - Butcher, T.

AU - Di Dio Cafiso, S.

AU - Cerantola, V.

AU - Chantel, J.

AU - Di Cicco, A.

AU - Coleman, A. L.

AU - Collier, J.

AU - Collins, G.

AU - Comley, A. J.

AU - Coppari, F.

AU - Cowan, T. E.

AU - Cristoforetti, G.

AU - Cynn, H.

AU - Descamps, A.

AU - Dorchies, F.

AU - Duff, M. J.

AU - Dwivedi, A.

AU - Edwards, C.

AU - Eggert, J. H.

AU - Errandonea, D.

AU - Fiquet, G.

AU - Galtier, E.

AU - Laso Garcia, A.

AU - Ginestet, H.

AU - Gizzi, L.

AU - Gleason, A.

AU - Goede, S.

AU - Gonzalez, J. M.

AU - Gorman, M. G.

AU - Harmand, M.

AU - Hartley, N. J.

AU - Hernandez-Gomez, C.

AU - Higginbotham, A.

AU - Höppner, H.

AU - Humphries, O. S.

AU - Husband, R. J.

AU - Hutchinson, T. M.

AU - Hwang, H.

AU - Keen, D. A.

AU - Kim, J.

AU - Koester, P.

AU - Konopkova, Z.

AU - Kraus, D.

AU - Krygier, A.

AU - Labate, L.

AU - Lazicki, A. E.

AU - Lee, Y.

AU - Liermann, H. P.

AU - Mason, P.

AU - Masruri, M.

AU - Massani, B.

AU - McBride, E. E.

AU - McGuire, C.

AU - McHardy, J. D.

AU - McGonegle, D.

AU - McWilliams, R. S.

AU - Merkel, S.

AU - Morard, G.

AU - Nagler, B.

AU - Nakatsutsumi, M.

AU - Nguyen-Cong, K.

AU - Norton, A. M.

AU - Oleynik, I. I.

AU - Otzen, C.

AU - Ozaki, N.

AU - Pandolfi, S.

AU - Pelka, A.

AU - Pereira, K. A.

AU - Phillips, J. P.

AU - Prescher, C.

AU - Preston, T.

AU - Randolph, L.

AU - Ranjan, D.

AU - Ravasio, A.

AU - Rips, J.

AU - Santamaria-Perez, D.

AU - Savage, D. J.

AU - Schoelmerich, M.

AU - Schwinkendorf, J. P.

AU - Singh, S.

AU - Smith, J.

AU - Smith, R. F.

AU - Sollier, A.

AU - Spear, J.

AU - Spindloe, C.

AU - Stevenson, M.

AU - Strohm, C.

AU - Suer, T. A.

AU - Tang, M.

AU - Toncian, M.

AU - Toncian, T.

AU - Tracy, S. J.

AU - Trapananti, A.

AU - Tschentscher, T.

AU - Tyldesley, M.

AU - Vennari, C. E.

AU - Vinci, T.

AU - Vogel, S. C.

AU - Volz, T. J.

AU - Vorberger, J.

AU - Willman, J. T.

AU - Wollenweber, L.

AU - Zastrau, U.

AU - Brambrink, E.

AU - Appel, K.

AU - McMahon, M. I.

PY - 2025/10/21

Y1 - 2025/10/21

N2 - We present a model of x-ray thermal diffuse scattering (TDS) from a cubic polycrystal with an arbitrary crystallographic texture, based on the classic approach of Warren [B. E. Warren, Acta Crystallogr. 6, 803 (1953)]. We compare the predictions of our model with femtosecond x-ray diffraction patterns gathered from ambient and dynamically compressed rolled copper foils obtained at the High Energy Density instrument of the European X-Ray Free-Electron Laser facility and find that the texture-aware TDS model yields more accurate results than does the conventional powder model owed to Warren. Nevertheless, we further show: with sufficient angular detector coverage, the TDS signal is largely unchanged by sample orientation and in all cases strongly resembles the signal from a perfectly random powder; shot-to-shot fluctuations in the TDS signal resulting from grain-sampling statistics are at the percent level, in stark contrast to the fluctuations in the Bragg-peak intensities (which are over an order of magnitude greater); and TDS is largely unchanged even following texture evolution caused by compression-induced plastic deformation. We conclude that TDS is robust against texture variation, making it a flexible temperature diagnostic applicable just as well to off-the-shelf commercial foils as to ideal powders.

AB - We present a model of x-ray thermal diffuse scattering (TDS) from a cubic polycrystal with an arbitrary crystallographic texture, based on the classic approach of Warren [B. E. Warren, Acta Crystallogr. 6, 803 (1953)]. We compare the predictions of our model with femtosecond x-ray diffraction patterns gathered from ambient and dynamically compressed rolled copper foils obtained at the High Energy Density instrument of the European X-Ray Free-Electron Laser facility and find that the texture-aware TDS model yields more accurate results than does the conventional powder model owed to Warren. Nevertheless, we further show: with sufficient angular detector coverage, the TDS signal is largely unchanged by sample orientation and in all cases strongly resembles the signal from a perfectly random powder; shot-to-shot fluctuations in the TDS signal resulting from grain-sampling statistics are at the percent level, in stark contrast to the fluctuations in the Bragg-peak intensities (which are over an order of magnitude greater); and TDS is largely unchanged even following texture evolution caused by compression-induced plastic deformation. We conclude that TDS is robust against texture variation, making it a flexible temperature diagnostic applicable just as well to off-the-shelf commercial foils as to ideal powders.

UR - https://www.scopus.com/pages/publications/105019216271

U2 - 10.1063/5.0295250

DO - 10.1063/5.0295250

M3 - Article

AN - SCOPUS:105019216271

SN - 0021-8979

VL - 138

JO - Journal of Applied Physics

JF - Journal of Applied Physics

IS - 15

M1 - 155903

ER -

X-ray thermal diffuse scattering as a texture-robust temperature diagnostic for dynamically compressed solids

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