6533b81ffe1ef96bd127735c

RESEARCH PRODUCT

Colossal Density-Driven Resistance Response in the Negative Charge Transfer Insulator MnS2

G. Alexander SmithNathan Dasenbrock-gammonAshkan SalamatDylan DurkeeDean SmithDean SmithKeith V. LawlerChristian ChildsElliot SniderSimon A. J. KimberRanga Dias

subject

Condensed Matter::Quantum GasesMaterials scienceValence (chemistry)Condensed matter physicsFermi levelGeneral Physics and AstronomyInsulator (electricity)Charge (physics)Antibonding molecular orbitalMetalCondensed Matter::Materials Sciencesymbols.namesakeElectrical resistance and conductancevisual_artsymbolsvisual_art.visual_art_mediumCondensed Matter::Strongly Correlated ElectronsDensity functional theory

description

A reversible density driven insulator to metal to insulator transition in high-spin MnS_{2} is experimentally observed, leading with a colossal electrical resistance drop of 10^{8}  Ω by 12 GPa. Density functional theory simulations reveal the metallization to be unexpectedly driven by previously unoccupied S_{2}^{2-} σ_{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.

yearjournalcountryeditionlanguage
2021-06-30Physical Review Letters
https://doi.org/10.1103/physrevlett.127.016401