Novel high-pressure monoclinic metallic phase of v 2 O 3

Yang Ding; Cheng Chien Chen; Qiaoshi Zeng; Heung Sik Kim; Myung Joon Han; Mahalingam Balasubramanian; Robert Gordon; Fangfei Li; Ligang Bai; Dimitry Popov; Steve M. Heald; Thomas Gog; Ho Kwang Mao; Michel Van Veenendaal

doi:10.1103/PhysRevLett.112.056401

Novel high-pressure monoclinic metallic phase of v 2 O 3

Yang Ding
, Cheng Chien Chen
, Qiaoshi Zeng
, Heung Sik Kim
, Myung Joon Han
, Mahalingam Balasubramanian
, Robert Gordon
, Fangfei Li
, Ligang Bai
, Dimitry Popov
, Steve M. Heald
, Thomas Gog
, Ho Kwang Mao
, Michel Van Veenendaal

Research output: Contribution to journal › Article › peer-review

54 Scopus citations

Abstract

Vanadium sesquioxide, V2O3, is a prototypical metal-to-insulator system where, in temperature-dependent studies, the transition always coincides with a corundum-to-monoclinic structural transition. As a function of pressure, V2O3 follows the expected behavior of increased metallicity due to a larger bandwidth for pressures up to 12.5 GPa. Surprisingly, for higher pressures when the structure becomes unstable, the resistance starts to increase. Around 32.5 GPa at 300 K, we observe a novel pressure-induced corundum-to-monoclinic transition between two metallic phases, showing that the structural phase transition can be decoupled from the metal-insulator transition. Using x-ray Raman scattering, we find that screening effects, which are strong in the corundum phase, become weakened at high pressures. Theoretical calculations indicate that this can be related to a decrease in coherent quasiparticle strength, suggesting that the high-pressure phase is likely a critical correlated metal, on the verge of Mott-insulating behavior.

Original language	English
Article number	056401
Journal	Physical Review Letters
Volume	112
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevLett.112.056401
State	Published - Feb 4 2014
Externally published	Yes

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title = "Novel high-pressure monoclinic metallic phase of v 2 O 3",

abstract = "Vanadium sesquioxide, V2O3, is a prototypical metal-to-insulator system where, in temperature-dependent studies, the transition always coincides with a corundum-to-monoclinic structural transition. As a function of pressure, V2O3 follows the expected behavior of increased metallicity due to a larger bandwidth for pressures up to 12.5 GPa. Surprisingly, for higher pressures when the structure becomes unstable, the resistance starts to increase. Around 32.5 GPa at 300 K, we observe a novel pressure-induced corundum-to-monoclinic transition between two metallic phases, showing that the structural phase transition can be decoupled from the metal-insulator transition. Using x-ray Raman scattering, we find that screening effects, which are strong in the corundum phase, become weakened at high pressures. Theoretical calculations indicate that this can be related to a decrease in coherent quasiparticle strength, suggesting that the high-pressure phase is likely a critical correlated metal, on the verge of Mott-insulating behavior.",

author = "Yang Ding and Chen, \{Cheng Chien\} and Qiaoshi Zeng and Kim, \{Heung Sik\} and Han, \{Myung Joon\} and Mahalingam Balasubramanian and Robert Gordon and Fangfei Li and Ligang Bai and Dimitry Popov and Heald, \{Steve M.\} and Thomas Gog and Mao, \{Ho Kwang\} and \{Van Veenendaal\}, Michel",

year = "2014",

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day = "4",

doi = "10.1103/PhysRevLett.112.056401",

language = "English",

volume = "112",

journal = "Physical Review Letters",

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T1 - Novel high-pressure monoclinic metallic phase of v 2 O 3

AU - Ding, Yang

AU - Chen, Cheng Chien

AU - Zeng, Qiaoshi

AU - Kim, Heung Sik

AU - Han, Myung Joon

AU - Balasubramanian, Mahalingam

AU - Gordon, Robert

AU - Li, Fangfei

AU - Bai, Ligang

AU - Popov, Dimitry

AU - Heald, Steve M.

AU - Gog, Thomas

AU - Mao, Ho Kwang

AU - Van Veenendaal, Michel

PY - 2014/2/4

Y1 - 2014/2/4

N2 - Vanadium sesquioxide, V2O3, is a prototypical metal-to-insulator system where, in temperature-dependent studies, the transition always coincides with a corundum-to-monoclinic structural transition. As a function of pressure, V2O3 follows the expected behavior of increased metallicity due to a larger bandwidth for pressures up to 12.5 GPa. Surprisingly, for higher pressures when the structure becomes unstable, the resistance starts to increase. Around 32.5 GPa at 300 K, we observe a novel pressure-induced corundum-to-monoclinic transition between two metallic phases, showing that the structural phase transition can be decoupled from the metal-insulator transition. Using x-ray Raman scattering, we find that screening effects, which are strong in the corundum phase, become weakened at high pressures. Theoretical calculations indicate that this can be related to a decrease in coherent quasiparticle strength, suggesting that the high-pressure phase is likely a critical correlated metal, on the verge of Mott-insulating behavior.

AB - Vanadium sesquioxide, V2O3, is a prototypical metal-to-insulator system where, in temperature-dependent studies, the transition always coincides with a corundum-to-monoclinic structural transition. As a function of pressure, V2O3 follows the expected behavior of increased metallicity due to a larger bandwidth for pressures up to 12.5 GPa. Surprisingly, for higher pressures when the structure becomes unstable, the resistance starts to increase. Around 32.5 GPa at 300 K, we observe a novel pressure-induced corundum-to-monoclinic transition between two metallic phases, showing that the structural phase transition can be decoupled from the metal-insulator transition. Using x-ray Raman scattering, we find that screening effects, which are strong in the corundum phase, become weakened at high pressures. Theoretical calculations indicate that this can be related to a decrease in coherent quasiparticle strength, suggesting that the high-pressure phase is likely a critical correlated metal, on the verge of Mott-insulating behavior.

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DO - 10.1103/PhysRevLett.112.056401

M3 - Article

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SN - 0031-9007

VL - 112

JO - Physical Review Letters

JF - Physical Review Letters

IS - 5

M1 - 056401

ER -

Novel high-pressure monoclinic metallic phase of v 2 O 3

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