Propagation of insulator-to-metal transition driven by photoinduced strain waves in a Mott material

Tatsuya Amano; Danylo Babich; Ritwika Mandal; Julio Guzman-Brambila; Alix Volte; Elzbieta Trzop; Marina Servol; Ernest Pastor; Maryam Alashoor; Jörgen Larsson; Andrius Jurgilaitis; Van Thai Pham; David Kroon; John Carl Ekström; Byungnam Ahn; Céline Mariette; Matteo Levantino; Mikhail Kozhaev; Julien Tranchant; Benoit Corraze; Laurent Cario; Mohammad Dolatabadi; Vinh Ta Phuoc; Rodolphe Sopracase; Mathieu Guillon; Hirotake Itoh; Yohei Kawakami; Yuto Nakamura; Hideo Kishida; Hervé Cailleau; Maciej Lorenc; Shinichiro Iwai; Etienne Janod

doi:10.1038/s41567-024-02628-4

Propagation of insulator-to-metal transition driven by photoinduced strain waves in a Mott material

Tatsuya Amano, Danylo Babich, Ritwika Mandal, Julio Guzman-Brambila, Alix Volte, Elzbieta Trzop, Marina Servol, Ernest Pastor, Maryam Alashoor, Jörgen Larsson, Andrius Jurgilaitis, Van Thai Pham, David Kroon, John Carl Ekström, Byungnam Ahn, Céline Mariette, Matteo Levantino, Mikhail Kozhaev, Julien Tranchant, Benoit CorrazeLaurent Cario, Mohammad Dolatabadi, Vinh Ta Phuoc, Rodolphe Sopracase, Mathieu Guillon, Hirotake Itoh, Yohei Kawakami, Yuto Nakamura, Hideo Kishida, Hervé Cailleau, Maciej Lorenc, Shinichiro Iwai, Etienne Janod

Forskningsoutput: Tidskriftsbidrag › Artikel i vetenskaplig tidskrift › Peer review

Sammanfattning

Ultrafast photoexcitation can generate internal compressive stress in Mott insulators that lead to strain waves from free surfaces. These photoinduced elastic waves can trigger phase transitions in materials. However, a comprehensive physical picture of the phase transformation dynamics that includes acoustic-scale propagation has not yet been developed. Here we demonstrate that such a strain-wave mechanism drives the ultrafast insulator-to-metal phase transition in granular thin films of the Mott material V2O3. Our time-resolved optical reflectivity and X-ray diffraction measurements reveal that an inverse ferroelastic shear occurs before the insulator-to-metal transition, which propagates in the wake of a compressive strain wave. These dynamics are governed by the domain size and film thickness, respectively. Our results clarify the morphological conditions for the ultrafast phase transition that is favoured in granular thin films and hindered in single crystals. The resulting physical picture sheds light on the ultrafast phase transitions in quantum materials and future devices based on Mott insulators.

Originalspråk	engelska
Tidskrift	Nature Physics
Volym	20
Nummer	11
DOI	https://doi.org/10.1038/s41567-024-02628-4
Status	Published - 2024

Ämnesklassifikation (UKÄ)

Den kondenserade materiens fysik (Här ingår: Materialfysik, nanofysik)

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10.1038/s41567-024-02628-4

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Amano, T., Babich, D., Mandal, R., Guzman-Brambila, J., Volte, A., Trzop, E., Servol, M., Pastor, E., Alashoor, M., Larsson, J., Jurgilaitis, A., Pham, V. T., Kroon, D., Ekström, J. C., Ahn, B., Mariette, C., Levantino, M., Kozhaev, M., Tranchant, J., ... Janod, E. (2024). Propagation of insulator-to-metal transition driven by photoinduced strain waves in a Mott material. Nature Physics, 20(11). https://doi.org/10.1038/s41567-024-02628-4

@article{1cfb83e4590346689a97f279918c8f0c,

title = "Propagation of insulator-to-metal transition driven by photoinduced strain waves in a Mott material",

abstract = "Ultrafast photoexcitation can generate internal compressive stress in Mott insulators that lead to strain waves from free surfaces. These photoinduced elastic waves can trigger phase transitions in materials. However, a comprehensive physical picture of the phase transformation dynamics that includes acoustic-scale propagation has not yet been developed. Here we demonstrate that such a strain-wave mechanism drives the ultrafast insulator-to-metal phase transition in granular thin films of the Mott material V2O3. Our time-resolved optical reflectivity and X-ray diffraction measurements reveal that an inverse ferroelastic shear occurs before the insulator-to-metal transition, which propagates in the wake of a compressive strain wave. These dynamics are governed by the domain size and film thickness, respectively. Our results clarify the morphological conditions for the ultrafast phase transition that is favoured in granular thin films and hindered in single crystals. The resulting physical picture sheds light on the ultrafast phase transitions in quantum materials and future devices based on Mott insulators.",

author = "Tatsuya Amano and Danylo Babich and Ritwika Mandal and Julio Guzman-Brambila and Alix Volte and Elzbieta Trzop and Marina Servol and Ernest Pastor and Maryam Alashoor and J{\"o}rgen Larsson and Andrius Jurgilaitis and Pham, {Van Thai} and David Kroon and Ekstr{\"o}m, {John Carl} and Byungnam Ahn and C{\'e}line Mariette and Matteo Levantino and Mikhail Kozhaev and Julien Tranchant and Benoit Corraze and Laurent Cario and Mohammad Dolatabadi and Phuoc, {Vinh Ta} and Rodolphe Sopracase and Mathieu Guillon and Hirotake Itoh and Yohei Kawakami and Yuto Nakamura and Hideo Kishida and Herv{\'e} Cailleau and Maciej Lorenc and Shinichiro Iwai and Etienne Janod",

year = "2024",

doi = "10.1038/s41567-024-02628-4",

language = "English",

volume = "20",

journal = "Nature Physics",

issn = "1745-2473",

publisher = "Nature Publishing Group",

number = "11",

}

Amano, T, Babich, D, Mandal, R, Guzman-Brambila, J, Volte, A, Trzop, E, Servol, M, Pastor, E, Alashoor, M, Larsson, J , Jurgilaitis, A , Pham, VT, Kroon, D, Ekström, JC, Ahn, B, Mariette, C, Levantino, M, Kozhaev, M, Tranchant, J, Corraze, B, Cario, L, Dolatabadi, M, Phuoc, VT, Sopracase, R, Guillon, M, Itoh, H, Kawakami, Y, Nakamura, Y, Kishida, H, Cailleau, H, Lorenc, M, Iwai, S & Janod, E 2024, 'Propagation of insulator-to-metal transition driven by photoinduced strain waves in a Mott material', Nature Physics, vol. 20, nr. 11. https://doi.org/10.1038/s41567-024-02628-4

TY - JOUR

T1 - Propagation of insulator-to-metal transition driven by photoinduced strain waves in a Mott material

AU - Amano, Tatsuya

AU - Babich, Danylo

AU - Mandal, Ritwika

AU - Guzman-Brambila, Julio

AU - Volte, Alix

AU - Trzop, Elzbieta

AU - Servol, Marina

AU - Pastor, Ernest

AU - Alashoor, Maryam

AU - Larsson, Jörgen

AU - Jurgilaitis, Andrius

AU - Pham, Van Thai

AU - Kroon, David

AU - Ekström, John Carl

AU - Ahn, Byungnam

AU - Mariette, Céline

AU - Levantino, Matteo

AU - Kozhaev, Mikhail

AU - Tranchant, Julien

AU - Corraze, Benoit

AU - Cario, Laurent

AU - Dolatabadi, Mohammad

AU - Phuoc, Vinh Ta

AU - Sopracase, Rodolphe

AU - Guillon, Mathieu

AU - Itoh, Hirotake

AU - Kawakami, Yohei

AU - Nakamura, Yuto

AU - Kishida, Hideo

AU - Cailleau, Hervé

AU - Lorenc, Maciej

AU - Iwai, Shinichiro

AU - Janod, Etienne

PY - 2024

Y1 - 2024

N2 - Ultrafast photoexcitation can generate internal compressive stress in Mott insulators that lead to strain waves from free surfaces. These photoinduced elastic waves can trigger phase transitions in materials. However, a comprehensive physical picture of the phase transformation dynamics that includes acoustic-scale propagation has not yet been developed. Here we demonstrate that such a strain-wave mechanism drives the ultrafast insulator-to-metal phase transition in granular thin films of the Mott material V2O3. Our time-resolved optical reflectivity and X-ray diffraction measurements reveal that an inverse ferroelastic shear occurs before the insulator-to-metal transition, which propagates in the wake of a compressive strain wave. These dynamics are governed by the domain size and film thickness, respectively. Our results clarify the morphological conditions for the ultrafast phase transition that is favoured in granular thin films and hindered in single crystals. The resulting physical picture sheds light on the ultrafast phase transitions in quantum materials and future devices based on Mott insulators.

AB - Ultrafast photoexcitation can generate internal compressive stress in Mott insulators that lead to strain waves from free surfaces. These photoinduced elastic waves can trigger phase transitions in materials. However, a comprehensive physical picture of the phase transformation dynamics that includes acoustic-scale propagation has not yet been developed. Here we demonstrate that such a strain-wave mechanism drives the ultrafast insulator-to-metal phase transition in granular thin films of the Mott material V2O3. Our time-resolved optical reflectivity and X-ray diffraction measurements reveal that an inverse ferroelastic shear occurs before the insulator-to-metal transition, which propagates in the wake of a compressive strain wave. These dynamics are governed by the domain size and film thickness, respectively. Our results clarify the morphological conditions for the ultrafast phase transition that is favoured in granular thin films and hindered in single crystals. The resulting physical picture sheds light on the ultrafast phase transitions in quantum materials and future devices based on Mott insulators.

UR - https://doi.org/10.1038/s41567-024-02699-3

U2 - 10.1038/s41567-024-02628-4

DO - 10.1038/s41567-024-02628-4

M3 - Article

AN - SCOPUS:85204175280

SN - 1745-2473

VL - 20

JO - Nature Physics

JF - Nature Physics

IS - 11

ER -

Propagation of insulator-to-metal transition driven by photoinduced strain waves in a Mott material

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