Pairing Symmetries of Unconventional High Temperature Superconductivity in a Zinc-Blende Structure

Abstract

We classify the pairing symmetries of three-dimensional superconductivity in the zinc-blende structure which can support an electronic environment to host unconventional high temperature superconductivity, and calculate the pairing symmetry in the presence of strong electron-electron correlation by the slave boson mean-field approach. We find that the d2z2-x2-y2 idx2-y2 pairing state, a three dimensional analogy of the d id pairing in a two dimensional square lattice, is ubiquitously favored near half filling upon hole doping in both single-orbital and three-orbital models. However, unlike the two dimensional counterpart, the Bogoliubov quasiparticle spectrum of the three dimensional state upholds the full Td point group symmetry and encompasses point nodes along certain high symmetric lines.