Seeing the orbital ordering in Iron-based superconductors with magnetic anisotropy

Abstract

The orbital fluctuation of the conduction electrons in the Iron-based superconductors is found to contribute significantly to the magnetic response of the system. With the use of a realistic five-band model and group theoretical analysis, we have determined the orbital magnetic susceptibility in such a multi-orbital system. At n=6.1, the in-plane orbital magnetic susceptibility is predicted to be about 10μB2/eV, which is more than 2/3 of the observed total susceptibility around 200 K in 122 systems(of about 14μB2/eV or 4.5×10-4erg/G2molASKlingeler). We find the in-plane orbital magnetic response is sensitive to the breaking of the tetragonal symmetry in the orbital space. In particular, when the observed band splitting(between the 3dxz and the 3dyz-dominated band) is used to estimate the strength of the symmetry breaking perturbationShen, a 4.5% modulation in the in-plane orbital magnetic susceptibility can be produced, making the latter a useful probe of the orbital ordering in such a multi-orbital system. As a by product, the theory also explains the large anisotropy between the in-plane and the out-of-plane magnetic response observed universally in susceptibility and NMR measurements.