Spin-driven nematic instability of the multiorbital Hubbard model: application to iron-based superconductors

Morten Holm Christensen; Jian Kang; Brian Møller Andersen; Rafael M. Fernandes

doi:10.1103/physrevb.93.085136

Spin-driven nematic instability of the multiorbital Hubbard model: application to iron-based superconductors

Morten Holm Christensen, Jian Kang, Brian Møller Andersen, Rafael M. Fernandes

Xray and Neutron Science

19 Citations (Scopus)

Abstract

Nematic order resulting from the partial melting of density waves has been proposed as the mechanism to explain nematicity in iron-based superconductors. An outstanding question, however, is whether the microscopic electronic model for these systems - the multiorbital Hubbard model - displays such an ordered state as its leading instability. In contrast to usual electronic instabilities, such as magnetic and charge order, this fluctuation-driven phenomenon cannot be captured by the standard random phase approximation (RPA) method. Here, by including fluctuations beyond RPA in the multiorbital Hubbard model, we derive its nematic susceptibility and contrast it with its ferro-orbital order susceptibility, showing that its leading instability is the spin-driven nematic phase. Our results also demonstrate the primary role played by the dxy orbital in driving the nematic transition and reveal that high-energy magnetic fluctuations are essential to stabilize nematic order in the absence of magnetic order.

Original language	English
Article number	085136
Journal	Physical Review B
Volume	93
Issue number	8
Number of pages	8
ISSN	2469-9950
DOIs	https://doi.org/10.1103/physrevb.93.085136
Publication status	Published - 25 Feb 2016

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title = "Spin-driven nematic instability of the multiorbital Hubbard model: application to iron-based superconductors",

abstract = "Nematic order resulting from the partial melting of density waves has been proposed as the mechanism to explain nematicity in iron-based superconductors. An outstanding question, however, is whether the microscopic electronic model for these systems - the multiorbital Hubbard model - displays such an ordered state as its leading instability. In contrast to usual electronic instabilities, such as magnetic and charge order, this fluctuation-driven phenomenon cannot be captured by the standard random phase approximation (RPA) method. Here, by including fluctuations beyond RPA in the multiorbital Hubbard model, we derive its nematic susceptibility and contrast it with its ferro-orbital order susceptibility, showing that its leading instability is the spin-driven nematic phase. Our results also demonstrate the primary role played by the dxy orbital in driving the nematic transition and reveal that high-energy magnetic fluctuations are essential to stabilize nematic order in the absence of magnetic order.",

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T1 - Spin-driven nematic instability of the multiorbital Hubbard model

T2 - application to iron-based superconductors

AU - Christensen, Morten Holm

AU - Kang, Jian

AU - Andersen, Brian Møller

AU - Fernandes, Rafael M.

PY - 2016/2/25

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N2 - Nematic order resulting from the partial melting of density waves has been proposed as the mechanism to explain nematicity in iron-based superconductors. An outstanding question, however, is whether the microscopic electronic model for these systems - the multiorbital Hubbard model - displays such an ordered state as its leading instability. In contrast to usual electronic instabilities, such as magnetic and charge order, this fluctuation-driven phenomenon cannot be captured by the standard random phase approximation (RPA) method. Here, by including fluctuations beyond RPA in the multiorbital Hubbard model, we derive its nematic susceptibility and contrast it with its ferro-orbital order susceptibility, showing that its leading instability is the spin-driven nematic phase. Our results also demonstrate the primary role played by the dxy orbital in driving the nematic transition and reveal that high-energy magnetic fluctuations are essential to stabilize nematic order in the absence of magnetic order.

AB - Nematic order resulting from the partial melting of density waves has been proposed as the mechanism to explain nematicity in iron-based superconductors. An outstanding question, however, is whether the microscopic electronic model for these systems - the multiorbital Hubbard model - displays such an ordered state as its leading instability. In contrast to usual electronic instabilities, such as magnetic and charge order, this fluctuation-driven phenomenon cannot be captured by the standard random phase approximation (RPA) method. Here, by including fluctuations beyond RPA in the multiorbital Hubbard model, we derive its nematic susceptibility and contrast it with its ferro-orbital order susceptibility, showing that its leading instability is the spin-driven nematic phase. Our results also demonstrate the primary role played by the dxy orbital in driving the nematic transition and reveal that high-energy magnetic fluctuations are essential to stabilize nematic order in the absence of magnetic order.

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Spin-driven nematic instability of the multiorbital Hubbard model: application to iron-based superconductors

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