Orbital-resolved vortex core states in FeSe Superconductors: calculation based on a three-orbital model

Abstract

We study electronic structure of vortex core states of FeSe superconductors based on a t2g three-orbital model by solving the Bogoliubov-de Gennes(BdG) equation self-consistently. The orbital-resolved vortex core states of different pairing symmetries manifest themselves as distinguishable structures due to different quasi-particle wavefunctions. The obtained vortices are classified in terms of the invariant subgroups of the symmetry group of the mean-field Hamiltonian in the presence of magnetic field. Isotropic s and anisotropic s wave vortices have G5 symmetry for each orbital, whereas dx2-y2 wave vortices show G*6 symmetry for dxz/yz orbitals and G*5 symmetry for dxy orbital. In the case of dx2-y2 wave vortices, hybridized-pairing between dxz and dyz orbitals gives rise to a relative phase difference in terms of gauge transformed pairing order parameters between dxz/yz and dxy orbitals, which is essentially caused by a transformation of co-representation of G*5 and G*6 subgroup. The calculated local density of states(LDOS) of dx2-y2 wave vortices show qualitatively similar pattern with experiment results. The phase difference of π4 between dxz/yz and dxy orbital-resolved dx2-y2 wave vortices can be verified by further experiment observation.