<p>Orbital-selective correlations have been observed to play an important role in Fe-based superconductors. Here, in contrast to previous site-local Mott transition-based origins, we present a band-theory-based mechanism for orbital-selective physics in monolayer FeSe, for which only electron pockets appear. Underlying our mechanism is the observation in density functional theory (DFT) calculations that around the M point in the Brillouin zone, antiferromagnetic fluctuations are strongly coupled to electrons in <i>x</i><sup>2</sup>&#xa0;−&#xa0;<i>y</i><sup>2</sup> orbitals but weakly coupled to those in {<i>x</i><i>z</i>,&#xa0;<i>y</i><i>z</i>} orbitals. Symmetry-arguments reveal that this orbital selective coupling originates from the different intertwined orbital and Fe-site sublattice Bloch wavefunctions for these two sets of orbitals at the M point, specifically, the <i>x</i><sup>2</sup>&#xa0;−&#xa0;<i>y</i><sup>2</sup> orbitals can be Fe-site localized. The strong coupling of electrons in <i>x</i><sup>2</sup>&#xa0;−&#xa0;<i>y</i><sup>2</sup> orbitals to the magnetic fluctuations enables orbital-selective electronic renormalizations that can account for important features of our angle-resolved photoemission spectroscopy measurements. Our symmetry-required mechanism for orbital selective physics can be generalized to a range of crystal space groups with four-fold and six-fold screw axes.</p>

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Symmetry-required orbital selectivity in monolayer FeSe

  • Mercè Roig,
  • Qiang Zou,
  • Basu Dev Oli,
  • Tatsuya Shishidou,
  • Yue Yu,
  • Huimin Zhang,
  • Daniel F. Agterberg,
  • Lian Li,
  • Michael Weinert

摘要

Orbital-selective correlations have been observed to play an important role in Fe-based superconductors. Here, in contrast to previous site-local Mott transition-based origins, we present a band-theory-based mechanism for orbital-selective physics in monolayer FeSe, for which only electron pockets appear. Underlying our mechanism is the observation in density functional theory (DFT) calculations that around the M point in the Brillouin zone, antiferromagnetic fluctuations are strongly coupled to electrons in x2 − y2 orbitals but weakly coupled to those in {xzyz} orbitals. Symmetry-arguments reveal that this orbital selective coupling originates from the different intertwined orbital and Fe-site sublattice Bloch wavefunctions for these two sets of orbitals at the M point, specifically, the x2 − y2 orbitals can be Fe-site localized. The strong coupling of electrons in x2 − y2 orbitals to the magnetic fluctuations enables orbital-selective electronic renormalizations that can account for important features of our angle-resolved photoemission spectroscopy measurements. Our symmetry-required mechanism for orbital selective physics can be generalized to a range of crystal space groups with four-fold and six-fold screw axes.