Nodal versus nodeless superconductivity in iso-electronic LiFeP and LiFeAs

Abstract

Nodal superconductivity is observed in LiFeP while its counterpart LiFeAs with similar topology and orbital content of the Fermi surfaces is a nodeless superconductor. We explain this difference by solving, in the two-Fe Brillouin zone, the frequency-dependent Eliashberg equations with spin-fluctuation mediated pairing interaction. Because of Fermi surface topology details, in LiFeAs all the Fe-t2g orbitals favor a common pairing symmetry. By contrast, in LiFeP the dxy orbital favors a pairing symmetry different from dxz/yz and their competition determines the pairing symmetry and the strength of the superconducting instability: dxy orbital strongly overcomes the others and imposes the symmetry of the superconducting order parameter. The leading pairing channel is a dxy-type state with nodes on both hole and electron Fermi surfaces. As a consequence, the dxz/yz electrons weakly pair leading to a reduced transition temperature in LiFeP.