Superconductivity in FeSe Thin Films Driven by the Interplay between Nematic Fluctuations and Spin-Orbit Coupling

Kang, Jian; Fernandes, Rafael M.

doi:10.1103/physrevlett.117.217003

Cited by 66 publications

(84 citation statements)

References 67 publications

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“…Interestingly a similar feature of such quasidegeneracy of sand d-wave solutions was obtained also in the spin fluctuation mechanism [5,31]. In addition, the exact degeneracy between s-and d-wave symmetry was found when nematic fluctuations are assumed independent from momentum and frequency [37]. The third, fourth, and fifth largest eigenvalues in Fig.…”

Section: Resultssupporting

confidence: 73%

Structure of the pairing gap from orbital nematic fluctuations

Agatsuma

Yamase

2016

Phys. Rev. B

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We study superconducting instability from orbital nematic fluctuations in a minimal model consisting of the d xz and d yz orbitals, and choose model parameters which capture the typical Fermi surface geometry observed in iron-based superconductors. We solve the Eliashberg equations down to low temperatures with keeping the renormalization function and a full momentum dependence of the pairing gap. When superconductivity occurs in the tetragonal phase, we find that the pairing gap exhibits a weak momentum dependence over the Fermi surfaces. The superconducting instability occurs also inside the nematic phase. When the d xz orbital is occupied more than the d yz orbital in the nematic phase, a larger (smaller) gap is realized on the Fermi-surface parts where the d xz (d yz ) orbital component is dominant, leading to a substantial momentum dependence of the pairing gap on the hole Fermi surfaces. On the other hand, the momentum dependence of the gap is weak on the electron Fermi surfaces. We also find that while the leading instability is the so-called s ++ -wave symmetry, the second leading one is d x 2 −y 2 -wave symmetry. In particular, these two states are nearly degenerate in the tetragonal phase, whereas such quasidegeneracy is lifted in the nematic phase and the d x 2 −y 2 -wave symmetry changes to highly anisotropic s-wave symmetry.

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Section: Resultssupporting

confidence: 73%

Structure of the pairing gap from orbital nematic fluctuations

Agatsuma

Yamase

2016

Phys. Rev. B

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“…As one theoretical study shows, the coupling of the d xy orbital to the nematic order parameter is necessary for predicting the correct gap symmetry in FeSe. 50 On the other hand, the energy scale of the band reconstruction shows a strong momentum dependence, indicating that the anisotropy is unlikely to be dominated by the on-site occupation difference between the d xz and d yz orbitals. Instead, other mechanisms must be considered to correctly describe the momentum-dependence orbital anisotropy.…”

Section: The Nematic Statementioning

confidence: 99%

Role of the orbital degree of freedom in iron-based superconductors

et al. 2017

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Almost a decade has passed since the serendipitous discovery of the iron-based high temperature superconductors (FeSCs) in 2008. The fact that, as in the copper oxide high temperature superconductors, long-range antiferromagnetism in the FeSCs arises in proximity to superconductivity immediately raised the question of the degree of similarity between the two. Despite the great resemblance in their phase diagrams, there exist important differences between the FeSCs and the cuprates that need to be considered in order to paint a full picture of these two families of high temperature superconductors. One of the key differences is the multi-orbital multi-band nature of the FeSCs, which contrasts with the effective single-band nature of the cuprates. Systematic studies of orbital related phenomena in FeSCs have been largely lacking. In this review, we summarize angle-resolved photoemission spectroscopy (ARPES) measurements across various FeSC families that have been reported in literature, focusing on the systematic trends of orbital dependent electron correlations and the role of different Fe 3d orbitals in driving the nematic transition, the spin-density-wave transition, and superconductivity.

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“…Since the less correlated iron phosphides also achieve relatively small

T_{c}

’s, it is reasonable to infer that moderate correlations are somehow favorable for superconductivity. In addition to driving large ‐scale band renormalizations, the electronic interactions are also believed to drive pairing in the FeSCs through the formation of antiferromagnetic spin fluctuations or possibly other electronic mechanisms .…”

Section: Introductionmentioning

confidence: 99%

“…Other fundamental and still unresolved questions concern the role of retardation (frequency) and the particular momentum dependence of the interactions responsible for pairing (dominated for instance by specific nesting vectors or small momentum transfers . A full accounting of all of these effects in detail is practically impossible for the multi ‐band Fermi surfaces present in the FeSC; nevertheless, the effective mass

m^{*}

of the quasiparticles near the Fermi level of a Fermi ‐liquid ‐like system can provide some insight into the overall strength of the many ‐body effects and the relevant interactions.…”

Section: Introductionmentioning

confidence: 99%

Constraints on the total coupling strengthto bosons in the iron based superconductors

Drechsler

Johnston

Grinenko

et al. 2017

Phys. Status Solidi B

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Despite the fact that the Fe-based superconductors (FeSCs) were discovered nearly ten years ago, the community is still devoting a tremendous effort towards elucidating their relevant microscopic pairing mechanism(s) and interactions. At present, there is still no consistent interpretation of their normal state properties, where the strength of the electron-electron interaction and the role of correlation effects are under debate. Here, we examine several common materials and illustrate various problems and concepts that are generic for all FeSCs. Based on empirical observations and qualitative insight from density functional theory, we show that the superconducting and low-energy thermodynamic properties of the FeSCs can be described semi-quantitively within multiband Eliashberg theory. We account for an important high-energy mass renormalization phenomenologically, and in agreement with constraints provided by thermodynamic, optical, and angle-resolved photoemission data. When seen in this way, all FeSCs with T c < 40 K studied so far are found to belong to an intermediate coupling regime. This finding is in contrast to the strong coupling scenarios proposed in the early period of the FeSC history. We also discuss several related issues, including the role of band shifts as measured by the positions of van Hove singularities, and the nature of a recently suggested quantum critical point in the strongly hole-doped systems AFe 2 As 2 (A = K, Rb, Cs). Using high-precision full relativistic GGA-band structure calculations, we arrive at a somewhat milder mass renormalization in comparison with previous studies. From the calculated mass anisotropies of all Fermi surface sheets, only the ε-pocket near the corner of the BZ is compatible with the experimentally observed anisotropy of the upper critical field, pointing to its dominant role in the superconductivity of these three compounds.

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Superconductivity in FeSe Thin Films Driven by the Interplay between Nematic Fluctuations and Spin-Orbit Coupling

Cited by 66 publications

References 67 publications

Structure of the pairing gap from orbital nematic fluctuations

Structure of the pairing gap from orbital nematic fluctuations

Role of the orbital degree of freedom in iron-based superconductors

Constraints on the total coupling strengthto bosons in the iron based superconductors

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