Imaging the itinerant-to-localized transmutation of electrons across the metal-to-insulator transition in V2O3

Maximilian Thees; Min Han Lee; Rosa Luca Bouwmeester; Pedro H. Rezende-Gonçalves; Emma David; Alexandre Zimmers; Franck Fortuna; Emmanouil Frantzeskakis; Nicolas M. Vargas; Yoav Kalcheim; Patrick Le Fèvre; Koji Horiba; Hiroshi Kumigashira; Silke Biermann; Juan Trastoy; Marcelo J. Rozenberg; Ivan K. Schuller; Andrés F. Santander-Syro

doi:10.1126/sciadv.abj1164

Imaging the itinerant-to-localized transmutation of electrons across the metal-to-insulator transition in V₂O₃

Maximilian Thees
, Min Han Lee
, Rosa Luca Bouwmeester
, Pedro H. Rezende-Gonçalves
, Emma David
, Alexandre Zimmers
, Franck Fortuna
, Emmanouil Frantzeskakis
, Nicolas M. Vargas
, Yoav Kalcheim
, Patrick Le Fèvre
, Koji Horiba
, Hiroshi Kumigashira
, Silke Biermann
, Juan Trastoy
, Marcelo J. Rozenberg
, Ivan K. Schuller
, Andrés F. Santander-Syro

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

Résumé

In solids, strong repulsion between electrons can inhibit their movement and result in a “Mott” metal-to-insulator transition (MIT), a fundamental phenomenon whose understanding has remained a challenge for over 50 years. A key issue is how the wave-like itinerant electrons change into a localized-like state due to increased interactions. However, observing the MIT in terms of the energy- and momentum-resolved electronic structure of the system, the only direct way to probe both itinerant and localized states, has been elusive. Here we show, using angle-resolved photoemission spectroscopy (ARPES), that in V₂O₃, the temperature-induced MIT is characterized by the progressive disappearance of its itinerant conduction band, without any change in its energy-momentum dispersion, and the simultaneous shift to larger binding energies of a quasi-localized state initially located near the Fermi level.

langue originale	Anglais
Numéro d'article	eabj1164
journal	Science Advances
Volume	7
Numéro de publication	45
Les DOIs	https://doi.org/10.1126/sciadv.abj1164
état	Publié - 1 nov. 2021

Accès au document

10.1126/sciadv.abj1164

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Thees, M., Lee, M. H., Bouwmeester, R. L., Rezende-Gonçalves, P. H., David, E., Zimmers, A., Fortuna, F., Frantzeskakis, E., Vargas, N. M., Kalcheim, Y., Fèvre, P. L., Horiba, K., Kumigashira, H., Biermann, S., Trastoy, J., Rozenberg, M. J., Schuller, I. K., & Santander-Syro, A. F. (2021). Imaging the itinerant-to-localized transmutation of electrons across the metal-to-insulator transition in V₂O₃. Science Advances, 7(45), Article eabj1164. https://doi.org/10.1126/sciadv.abj1164

@article{ffe4a0c73d424c38b948173696c20ba3,

title = "Imaging the itinerant-to-localized transmutation of electrons across the metal-to-insulator transition in V2O3",

abstract = "In solids, strong repulsion between electrons can inhibit their movement and result in a “Mott” metal-to-insulator transition (MIT), a fundamental phenomenon whose understanding has remained a challenge for over 50 years. A key issue is how the wave-like itinerant electrons change into a localized-like state due to increased interactions. However, observing the MIT in terms of the energy- and momentum-resolved electronic structure of the system, the only direct way to probe both itinerant and localized states, has been elusive. Here we show, using angle-resolved photoemission spectroscopy (ARPES), that in V2O3, the temperature-induced MIT is characterized by the progressive disappearance of its itinerant conduction band, without any change in its energy-momentum dispersion, and the simultaneous shift to larger binding energies of a quasi-localized state initially located near the Fermi level.",

author = "Maximilian Thees and Lee, \{Min Han\} and Bouwmeester, \{Rosa Luca\} and Rezende-Gon{\c c}alves, \{Pedro H.\} and Emma David and Alexandre Zimmers and Franck Fortuna and Emmanouil Frantzeskakis and Vargas, \{Nicolas M.\} and Yoav Kalcheim and F{\`e}vre, \{Patrick Le\} and Koji Horiba and Hiroshi Kumigashira and Silke Biermann and Juan Trastoy and Rozenberg, \{Marcelo J.\} and Schuller, \{Ivan K.\} and Santander-Syro, \{Andr{\'e}s F.\}",

note = "Publisher Copyright: Copyright {\textcopyright} 2021 The Authors, some rights reserved;",

year = "2021",

month = nov,

day = "1",

doi = "10.1126/sciadv.abj1164",

language = "English",

volume = "7",

journal = "Science Advances",

issn = "2375-2548",

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Thees, M, Lee, MH, Bouwmeester, RL, Rezende-Gonçalves, PH, David, E, Zimmers, A, Fortuna, F, Frantzeskakis, E, Vargas, NM, Kalcheim, Y, Fèvre, PL, Horiba, K, Kumigashira, H, Biermann, S, Trastoy, J, Rozenberg, MJ, Schuller, IK & Santander-Syro, AF 2021, 'Imaging the itinerant-to-localized transmutation of electrons across the metal-to-insulator transition in V₂O₃', Science Advances, VOL. 7, Numéro 45, eabj1164. https://doi.org/10.1126/sciadv.abj1164

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T1 - Imaging the itinerant-to-localized transmutation of electrons across the metal-to-insulator transition in V2O3

AU - Thees, Maximilian

AU - Lee, Min Han

AU - Bouwmeester, Rosa Luca

AU - Rezende-Gonçalves, Pedro H.

AU - David, Emma

AU - Zimmers, Alexandre

AU - Fortuna, Franck

AU - Frantzeskakis, Emmanouil

AU - Vargas, Nicolas M.

AU - Kalcheim, Yoav

AU - Fèvre, Patrick Le

AU - Horiba, Koji

AU - Kumigashira, Hiroshi

AU - Biermann, Silke

AU - Trastoy, Juan

AU - Rozenberg, Marcelo J.

AU - Schuller, Ivan K.

AU - Santander-Syro, Andrés F.

PY - 2021/11/1

Y1 - 2021/11/1

N2 - In solids, strong repulsion between electrons can inhibit their movement and result in a “Mott” metal-to-insulator transition (MIT), a fundamental phenomenon whose understanding has remained a challenge for over 50 years. A key issue is how the wave-like itinerant electrons change into a localized-like state due to increased interactions. However, observing the MIT in terms of the energy- and momentum-resolved electronic structure of the system, the only direct way to probe both itinerant and localized states, has been elusive. Here we show, using angle-resolved photoemission spectroscopy (ARPES), that in V2O3, the temperature-induced MIT is characterized by the progressive disappearance of its itinerant conduction band, without any change in its energy-momentum dispersion, and the simultaneous shift to larger binding energies of a quasi-localized state initially located near the Fermi level.

AB - In solids, strong repulsion between electrons can inhibit their movement and result in a “Mott” metal-to-insulator transition (MIT), a fundamental phenomenon whose understanding has remained a challenge for over 50 years. A key issue is how the wave-like itinerant electrons change into a localized-like state due to increased interactions. However, observing the MIT in terms of the energy- and momentum-resolved electronic structure of the system, the only direct way to probe both itinerant and localized states, has been elusive. Here we show, using angle-resolved photoemission spectroscopy (ARPES), that in V2O3, the temperature-induced MIT is characterized by the progressive disappearance of its itinerant conduction band, without any change in its energy-momentum dispersion, and the simultaneous shift to larger binding energies of a quasi-localized state initially located near the Fermi level.

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