Colossal Density-Driven Resistance Response in the Negative Charge Transfer Insulator MnS2 (Publication with Expression of Concern. See vol. 130, 2023) (Retracted Article)

Colossal Density-Driven Resistance Response in the Negative Charge Transfer Insulator MnS2 (Publication with Expression of Concern. See vol. 130, 2023) (Retracted Article)

A reversible density driven insulator to metal to insulator transition in high-spin MnS2 is experimentally observed, leading with a colossal electrical resistance drop of 10(8) Omega by 12 GPa. Density functional theory simulations reveal the metallization to be unexpectedly driven by previously uno...

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Veröffentlicht in:Physical review letters 2021-07, Vol.127 (1), p.1, Article 016401
Hauptverfasser: Durkee, Dylan, Dasenbrock-Gammon, Nathan, Smith, G. Alexander, Snider, Elliot, Smith, Dean, Childs, Christian, Kimber, Simon A. J., Lawler, Keith, Dias, Ranga P., Salamat, Ashkan
Format: Artikel
Sprache:eng
Schlagworte:
70 PLASMA PHYSICS AND FUSION TECHNOLOGY
Arsenopyrite
ATOMIC AND MOLECULAR PHYSICS
Charge transfer
Density functional theory
electrical conductivity
Electron states
electronic structure
Insulators
Metallicity
Metallizing
phase diagrams
Physical Sciences
Physics
Physics, Multidisciplinary
Science & Technology
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Zusammenfassung:A reversible density driven insulator to metal to insulator transition in high-spin MnS2 is experimentally observed, leading with a colossal electrical resistance drop of 10(8) Omega by 12 GPa. Density functional theory simulations reveal the metallization to be unexpectedly driven by previously unoccupied S-2(-2) sigma*(3p) antibonding states crossing the Fermi level. This is a unique variant of the charge transfer insulator to metal transition for negative charge transfer insulators having anions with an unsaturated valence. By 36 GPa the emergence of the low-spin insulating arsenopyrite (P2(1)/c) is confirmed, and the bulk metallicity is broken with the system returning to an insulative electronic state.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.127.016401