Osmates on the Verge of a Hund's-Mott Transition: The Different Fates of NaOsO3 and LiOsO3

Daniel Springer; Bongjae Kim; Peitao Liu; Sergii Khmelevskyi; Severino Adler; Massimo Capone; Giorgio Sangiovanni; Cesare Franchini; Alessandro Toschi

doi:10.1103/PhysRevLett.125.166402

Osmates on the Verge of a Hund's-Mott Transition: The Different Fates of NaOsO3 and LiOsO3

Daniel Springer, Bongjae Kim, Peitao Liu, Sergii Khmelevskyi, Severino Adler, Massimo Capone, Giorgio Sangiovanni, Cesare Franchini, Alessandro Toschi

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Abstract

We clarify the origin of the strikingly different spectroscopic properties of the chemically similar compounds NaOsO3 and LiOsO3. Our first-principle, many-body analysis demonstrates that the highly sensitive physics of these two materials is controlled by their proximity to an adjacent Hund's-Mott insulating phase. Although 5d oxides are mildly correlated, we show that the cooperative action of intraorbital repulsion and Hund's exchange becomes the dominant physical mechanism in these materials if their t2g shell is half filled. Small material specific details hence result in an extremely sharp change of the electronic mobility, explaining the surprisingly different properties of the paramagnetic high-temperature phases of the two compounds.

Original language	English
Article number	166402
Journal	Physical Review Letters
Volume	125
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevLett.125.166402
State	Published - Oct 2020

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title = "Osmates on the Verge of a Hund's-Mott Transition: The Different Fates of NaOsO3 and LiOsO3",

abstract = "We clarify the origin of the strikingly different spectroscopic properties of the chemically similar compounds NaOsO3 and LiOsO3. Our first-principle, many-body analysis demonstrates that the highly sensitive physics of these two materials is controlled by their proximity to an adjacent Hund's-Mott insulating phase. Although 5d oxides are mildly correlated, we show that the cooperative action of intraorbital repulsion and Hund's exchange becomes the dominant physical mechanism in these materials if their t2g shell is half filled. Small material specific details hence result in an extremely sharp change of the electronic mobility, explaining the surprisingly different properties of the paramagnetic high-temperature phases of the two compounds.",

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AU - Kim, Bongjae

AU - Liu, Peitao

AU - Khmelevskyi, Sergii

AU - Adler, Severino

AU - Capone, Massimo

AU - Sangiovanni, Giorgio

AU - Franchini, Cesare

AU - Toschi, Alessandro

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AB - We clarify the origin of the strikingly different spectroscopic properties of the chemically similar compounds NaOsO3 and LiOsO3. Our first-principle, many-body analysis demonstrates that the highly sensitive physics of these two materials is controlled by their proximity to an adjacent Hund's-Mott insulating phase. Although 5d oxides are mildly correlated, we show that the cooperative action of intraorbital repulsion and Hund's exchange becomes the dominant physical mechanism in these materials if their t2g shell is half filled. Small material specific details hence result in an extremely sharp change of the electronic mobility, explaining the surprisingly different properties of the paramagnetic high-temperature phases of the two compounds.

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Osmates on the Verge of a Hund's-Mott Transition: The Different Fates of NaOsO3 and LiOsO3

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