Particle-Hole Transformation in Strongly-Doped Iron-Based Superconductors

Abstract

An exact particle-hole transformation is discovered in a local-moment model for a single layer of heavily electron-doped FeSe. The model harbors hidden magnetic order between the iron dxz and dyz orbitals at the wavenumber (pi,pi). It potentially is tied to the magnetic resonances about the very same Neel ordering vector that have been recently discovered in intercalated FeSe. Upon electron doping, the local-moment model successfully accounts for the electron-pocket Fermi surfaces observed experimentally at the corner of the two-iron Brillouin zone in electron-doped FeSe, as well as for isotropic Cooper pairs. Application of the particle-hole transformation predicts a surface-layer iron-based superconductor at strong hole doping that exhibits high Tc, and that shows hole-type Fermi-surface pockets at the center of the two-iron Brillouin zone.