Ultrafast and persistent photoinduced phase transition at room temperature monitored by streaming powder diffraction

Marius Hervé; Gaël Privault; Elzbieta Trzop; Shintaro Akagi; Yves Watier; Serhane Zerdane; Ievgeniia Chaban; Ricardo G. Torres Ramírez; Celine Mariette; Alix Volte; Marco Cammarata; Matteo Levantino; Hiroko Tokoro; Shin ichi Ohkoshi; Eric Collet

doi:10.1038/s41467-023-44440-3

Ultrafast and persistent photoinduced phase transition at room temperature monitored by streaming powder diffraction

Marius Hervé
, Gaël Privault
, Elzbieta Trzop
, Shintaro Akagi
, Yves Watier
, Serhane Zerdane
, Ievgeniia Chaban
, Ricardo G. Torres Ramírez
, Celine Mariette
, Alix Volte
, Marco Cammarata
, Matteo Levantino
, Hiroko Tokoro
, Shin ichi Ohkoshi
, Eric Collet

IPR (Institut de Physique de Rennes) - UMR 6251
Centre national de la recherche scientifique
University of Tsukuba
European Synchrotron Radiation Facility
Paul Scherrer Institut
University of Tokyo
Institut Universitaire de France

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

Abstract

Ultrafast photoinduced phase transitions at room temperature, driven by a single laser shot and persisting long after stimuli, represent emerging routes for ultrafast control over materials’ properties. Time-resolved studies provide fundamental mechanistic insight into far-from-equilibrium electronic and structural dynamics. Here we study the photoinduced phase transformation of the Rb_0.94Mn_0.94Co_0.06[Fe(CN)₆]_0.98 material, designed to exhibit a 75 K wide thermal hysteresis around room temperature between Mn^IIIFe^II tetragonal and Mn^IIFe^III cubic phases. We developed a specific powder sample streaming technique to monitor by ultrafast X-ray diffraction the structural and symmetry changes. We show that the photoinduced polarons expand the lattice, while the tetragonal-to-cubic photoinduced phase transition occurs within 100 ps above threshold fluence. These results are rationalized within the framework of the Landau theory of phase transition as an elastically-driven and cooperative process. We foresee broad applications of the streaming powder technique to study non-reversible and ultrafast dynamics.

Original language	English
Article number	267
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-44440-3
Publication status	Published - 1 Dec 2024

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Hervé, M., Privault, G., Trzop, E., Akagi, S., Watier, Y., Zerdane, S., Chaban, I., Torres Ramírez, R. G., Mariette, C., Volte, A., Cammarata, M., Levantino, M., Tokoro, H., Ohkoshi, S. I., & Collet, E. (2024). Ultrafast and persistent photoinduced phase transition at room temperature monitored by streaming powder diffraction. Nature Communications, 15(1), Article 267. https://doi.org/10.1038/s41467-023-44440-3

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title = "Ultrafast and persistent photoinduced phase transition at room temperature monitored by streaming powder diffraction",

abstract = "Ultrafast photoinduced phase transitions at room temperature, driven by a single laser shot and persisting long after stimuli, represent emerging routes for ultrafast control over materials{\textquoteright} properties. Time-resolved studies provide fundamental mechanistic insight into far-from-equilibrium electronic and structural dynamics. Here we study the photoinduced phase transformation of the Rb0.94Mn0.94Co0.06[Fe(CN)6]0.98 material, designed to exhibit a 75 K wide thermal hysteresis around room temperature between MnIIIFeII tetragonal and MnIIFeIII cubic phases. We developed a specific powder sample streaming technique to monitor by ultrafast X-ray diffraction the structural and symmetry changes. We show that the photoinduced polarons expand the lattice, while the tetragonal-to-cubic photoinduced phase transition occurs within 100 ps above threshold fluence. These results are rationalized within the framework of the Landau theory of phase transition as an elastically-driven and cooperative process. We foresee broad applications of the streaming powder technique to study non-reversible and ultrafast dynamics.",

author = "Marius Herv{\'e} and Ga{\"e}l Privault and Elzbieta Trzop and Shintaro Akagi and Yves Watier and Serhane Zerdane and Ievgeniia Chaban and \{Torres Ram{\'i}rez\}, \{Ricardo G.\} and Celine Mariette and Alix Volte and Marco Cammarata and Matteo Levantino and Hiroko Tokoro and Ohkoshi, \{Shin ichi\} and Eric Collet",

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doi = "10.1038/s41467-023-44440-3",

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Hervé, M, Privault, G, Trzop, E, Akagi, S, Watier, Y, Zerdane, S, Chaban, I, Torres Ramírez, RG, Mariette, C, Volte, A, Cammarata, M, Levantino, M, Tokoro, H, Ohkoshi, SI & Collet, E 2024, 'Ultrafast and persistent photoinduced phase transition at room temperature monitored by streaming powder diffraction', Nature Communications, vol. 15, no. 1, 267. https://doi.org/10.1038/s41467-023-44440-3

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T1 - Ultrafast and persistent photoinduced phase transition at room temperature monitored by streaming powder diffraction

AU - Hervé, Marius

AU - Privault, Gaël

AU - Trzop, Elzbieta

AU - Akagi, Shintaro

AU - Watier, Yves

AU - Zerdane, Serhane

AU - Chaban, Ievgeniia

AU - Torres Ramírez, Ricardo G.

AU - Mariette, Celine

AU - Volte, Alix

AU - Cammarata, Marco

AU - Levantino, Matteo

AU - Tokoro, Hiroko

AU - Ohkoshi, Shin ichi

AU - Collet, Eric

PY - 2024/12/1

Y1 - 2024/12/1

N2 - Ultrafast photoinduced phase transitions at room temperature, driven by a single laser shot and persisting long after stimuli, represent emerging routes for ultrafast control over materials’ properties. Time-resolved studies provide fundamental mechanistic insight into far-from-equilibrium electronic and structural dynamics. Here we study the photoinduced phase transformation of the Rb0.94Mn0.94Co0.06[Fe(CN)6]0.98 material, designed to exhibit a 75 K wide thermal hysteresis around room temperature between MnIIIFeII tetragonal and MnIIFeIII cubic phases. We developed a specific powder sample streaming technique to monitor by ultrafast X-ray diffraction the structural and symmetry changes. We show that the photoinduced polarons expand the lattice, while the tetragonal-to-cubic photoinduced phase transition occurs within 100 ps above threshold fluence. These results are rationalized within the framework of the Landau theory of phase transition as an elastically-driven and cooperative process. We foresee broad applications of the streaming powder technique to study non-reversible and ultrafast dynamics.

AB - Ultrafast photoinduced phase transitions at room temperature, driven by a single laser shot and persisting long after stimuli, represent emerging routes for ultrafast control over materials’ properties. Time-resolved studies provide fundamental mechanistic insight into far-from-equilibrium electronic and structural dynamics. Here we study the photoinduced phase transformation of the Rb0.94Mn0.94Co0.06[Fe(CN)6]0.98 material, designed to exhibit a 75 K wide thermal hysteresis around room temperature between MnIIIFeII tetragonal and MnIIFeIII cubic phases. We developed a specific powder sample streaming technique to monitor by ultrafast X-ray diffraction the structural and symmetry changes. We show that the photoinduced polarons expand the lattice, while the tetragonal-to-cubic photoinduced phase transition occurs within 100 ps above threshold fluence. These results are rationalized within the framework of the Landau theory of phase transition as an elastically-driven and cooperative process. We foresee broad applications of the streaming powder technique to study non-reversible and ultrafast dynamics.

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DO - 10.1038/s41467-023-44440-3

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AN - SCOPUS:85182995333

SN - 2041-1723

VL - 15

JO - Nature Communications

JF - Nature Communications

IS - 1

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ER -

Ultrafast and persistent photoinduced phase transition at room temperature monitored by streaming powder diffraction

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