Pairing symmetry and topological surface state in iron-chalcogenide superconductors

Abstract

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The symmetries of superconducting gap functions remain an important issue in iron-based superconductivity. Motivated by the recent angle-resolved photoemission spectroscopic measurements of iron-chalcogenide superconductors, we investigate the influence of pairing symmetries on the topological surface state. If the surface Dirac cone becomes gapped in the superconducting phase, it implies magnetization induced from time-reversal symmetry-breaking pairing via spin-orbit coupling. Based on the crystalline symmetry constraints on the Ginzburg-Landau free energy, the gap function symmetries are among the possibilities of A_{1g(u)}±iA_{2g(u)}, B_{1g(u)}±iB_{2g(u)}, or E_{g(u)}±iE_{g(u)}. This time-reversal symmetry-breaking effect can exist in the normal state very close to T_{c} with the relative phase between two gap functions locked at ±π/2. The coupling between magnetization and superconducting gap functions is calculated based on a three-orbital model for the band structure of iron chalcogenides. This study provides the connection between the gap function symmetries and topological properties of the surface state.