Density functional study of FeS, FeSe, and FeTe: Electronic structure, magnetism, phonons, and superconductivity

Alaska Subedi; Lijun Zhang; D. J. Singh; M. H. Du

doi:10.1103/PhysRevB.78.134514

Density functional study of FeS, FeSe, and FeTe: Electronic structure, magnetism, phonons, and superconductivity

Alaska Subedi
, Lijun Zhang
, D. J. Singh
, M. H. Du

University of Tennessee
Oak Ridge National Laboratory

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

Abstract

We report density functional calculations of the electronic structure, Fermi surface, phonon spectrum, magnetism, and electron-phonon coupling for the superconducting phase FeSe, as well as the related compounds FeS and FeTe. We find that the Fermi-surface structure of these compounds is very similar to that of the Fe-As based superconductors, with cylindrical electron sections at the zone corner, cylindrical hole surface sections, and depending on the compound, other small hole sections at the zone center. As in the Fe-As based materials, these surfaces are separated by a two-dimensional nesting vector at (π,π). The density of states, nesting, and Fermi-surface size increase, going from FeSe to FeTe. Both FeSe and FeTe show spin-density wave (SDW) ground states, while FeS is close to instability. In a scenario where superconductivity is mediated by spin fluctuations at the SDW nesting vector, the strongest superconductor in this series would be doped FeTe.

Original language	English
Article number	134514
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	78
Issue number	13
DOIs	https://doi.org/10.1103/PhysRevB.78.134514
Publication status	Published - 13 Oct 2008
Externally published	Yes

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title = "Density functional study of FeS, FeSe, and FeTe: Electronic structure, magnetism, phonons, and superconductivity",

abstract = "We report density functional calculations of the electronic structure, Fermi surface, phonon spectrum, magnetism, and electron-phonon coupling for the superconducting phase FeSe, as well as the related compounds FeS and FeTe. We find that the Fermi-surface structure of these compounds is very similar to that of the Fe-As based superconductors, with cylindrical electron sections at the zone corner, cylindrical hole surface sections, and depending on the compound, other small hole sections at the zone center. As in the Fe-As based materials, these surfaces are separated by a two-dimensional nesting vector at (π,π). The density of states, nesting, and Fermi-surface size increase, going from FeSe to FeTe. Both FeSe and FeTe show spin-density wave (SDW) ground states, while FeS is close to instability. In a scenario where superconductivity is mediated by spin fluctuations at the SDW nesting vector, the strongest superconductor in this series would be doped FeTe.",

author = "Alaska Subedi and Lijun Zhang and Singh, \{D. J.\} and Du, \{M. H.\}",

year = "2008",

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doi = "10.1103/PhysRevB.78.134514",

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journal = "Physical Review B - Condensed Matter and Materials Physics",

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T1 - Density functional study of FeS, FeSe, and FeTe

T2 - Electronic structure, magnetism, phonons, and superconductivity

AU - Subedi, Alaska

AU - Zhang, Lijun

AU - Singh, D. J.

AU - Du, M. H.

PY - 2008/10/13

Y1 - 2008/10/13

N2 - We report density functional calculations of the electronic structure, Fermi surface, phonon spectrum, magnetism, and electron-phonon coupling for the superconducting phase FeSe, as well as the related compounds FeS and FeTe. We find that the Fermi-surface structure of these compounds is very similar to that of the Fe-As based superconductors, with cylindrical electron sections at the zone corner, cylindrical hole surface sections, and depending on the compound, other small hole sections at the zone center. As in the Fe-As based materials, these surfaces are separated by a two-dimensional nesting vector at (π,π). The density of states, nesting, and Fermi-surface size increase, going from FeSe to FeTe. Both FeSe and FeTe show spin-density wave (SDW) ground states, while FeS is close to instability. In a scenario where superconductivity is mediated by spin fluctuations at the SDW nesting vector, the strongest superconductor in this series would be doped FeTe.

AB - We report density functional calculations of the electronic structure, Fermi surface, phonon spectrum, magnetism, and electron-phonon coupling for the superconducting phase FeSe, as well as the related compounds FeS and FeTe. We find that the Fermi-surface structure of these compounds is very similar to that of the Fe-As based superconductors, with cylindrical electron sections at the zone corner, cylindrical hole surface sections, and depending on the compound, other small hole sections at the zone center. As in the Fe-As based materials, these surfaces are separated by a two-dimensional nesting vector at (π,π). The density of states, nesting, and Fermi-surface size increase, going from FeSe to FeTe. Both FeSe and FeTe show spin-density wave (SDW) ground states, while FeS is close to instability. In a scenario where superconductivity is mediated by spin fluctuations at the SDW nesting vector, the strongest superconductor in this series would be doped FeTe.

UR - https://www.scopus.com/pages/publications/55149112339

U2 - 10.1103/PhysRevB.78.134514

DO - 10.1103/PhysRevB.78.134514

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SN - 1098-0121

VL - 78

JO - Physical Review B - Condensed Matter and Materials Physics

JF - Physical Review B - Condensed Matter and Materials Physics

IS - 13

M1 - 134514

ER -

Density functional study of FeS, FeSe, and FeTe: Electronic structure, magnetism, phonons, and superconductivity

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