Pairing Mechanism of the Heavily Electron Doped FeSe Systems: Dynamical Tuning of the Pairing Cutoff Energy

Abstract

We studied pairing mechanism of the heavily electron doped FeSe (HEDIS) systems, which commonly have one incipient hole band -- a band top below the Fermi level by a finite energy distance εb -- at point and ordinary electron bands at M points in Brillouin zone (BZ). We found that the system allows two degenerate superconducting solutions with the exactly same Tc in clean limit: the incipient she-gap (h- ≠ 0, e+ ≠ 0) and see++-gap (h =0, e+ ≠ 0) solutions with different pairing cutoffs, sf (spin fluctuation energy) and εb, respectively. The see++-gap solution, in which the system dynamically renormalizes the original pairing cutoff sf to phys=εb (< sf), therefore actively eliminates the incipient hole band from forming Cooper pairs, but without loss of Tc, becomes immune to the impurity pair-breaking. As a result, the HEDIS systems, by dynamically tuning the pairing cutoff and selecting the see++-pairing state, can always achieve the maximum Tc -- the Tc of the degenerate she solution in the ideal clean limit -- latent in the original pairing interactions, even in dirty limit.