Superconductivity Mediated by Nematic Fluctuations in Tetragonal FeSe<sub>1-x</sub>S<sub>x</sub>.

ORAL  · Invited

Abstract

Electronic nematic exist in several families of unconventional superconductors. Although superconductivity mediated by nematic fluctuations is well established theoretically [1-4], it has yet to be unambiguously identified experimentally [5, 6]. A major challenge is that nematicity is often intertwined with other degrees of freedom, such as magnetism and charge order. The FeSe1−xSx family of iron-based superconductors provides a unique opportunity to explore this concept, as it features an isolated nematic phase that can be suppressed by sulfur substitution at a quantum critical point (QCP) near xc = 0.17, where nematic fluctuations are the largest [7, 8]. We performed scanning tunneling spectroscopy measurements to visualize Boguliubov quasiparticle interference patterns, from which we determined the momentum structure of the superconducting gap near the Brillouin zone Γ point of FeSe0.81S0.19. The results reveal an anisotropic, near nodal gap with minima that are 45° rotated with respect to the Fe-Fe direction, characteristic of a nematic pairing interaction. In contrast, the gap maxima in pristine FeSe are aligned with the Fe-Fe direction. Thus, the measurements reveal a gap structure that not only is at odds with general expectations from the traditional spin-fluctuation scenario, but which also displays the form expected for superconductivity mediated by nematic fluctuations. While the qualitative analysis of the data already supports the scenario of superconductivity due to nematic fluctuations, we also made a quantitative comparison with a theoretical model, further substantiating our conclusions.



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*NSF DMR-2034345, Alfred P. Sloan Fellowship, UC Lab Fees Research Program (LFR-20-653926), DOE-BES DE-SC0020045, CNPq-Brazil 309584/2021-3.

Publication: Pranab Kumar Nag, Kirsty Scott et al. Superconductivity Mediated by Nematic Fluctuations in Tetragonal Fe(Se,S).

Presenters

  • Eduardo H Da Silva Neto

    • Yale University

Authors

  • Eduardo H Da Silva Neto

    • Yale University

  • Pranab Kumar Nag

    • Yale University

  • Kirsty Scott

    • Yale University

  • Vanuildo Carvalho

    • Universidade Federal de Goias
    • Instituto de Física, Universidade Federal de Goiás, 74.001-970, Goiânia-GO, Brazil
    • Universidade Federal de Goiás

  • Journey K Byland

    • University of California, Davis

  • Xinze Yang

    • Yale University

  • Aaron G Greenberg

    • Yale University

  • Morgan Walker

    • University of California, Davis
    • UC Davis

  • Peter Klavins

    • University of California, Davis

  • Eduardo Miranda

    • Gleb Wataghin Institute of Physics, University of Campinas, Campinas, São Paulo 13083-950, Brazil
    • University of Campinas

  • Adrian Gozar

    • Yale University

  • Valentin Taufour

    • UC Davis
    • University of California, Davis

  • Rafael M Fernandes

    • University of Minnesota