Modulated superconductivity due to vacancy and magnetic order in AxFe2-x/2Se2 [A=Cs, K, (Tl,Rb), (Tl,K)] iron-selenide superconductors

Abstract

We present a calculation of a 'modulated' superconducting state in iron-selenide superconductors. The zero-momentum d-wave pairing breaks the translational symmetry of the conventional BaFe2Se2-like crystal of I4/mmm space group. This pairing state becomes compatible when the Fe vacancies form an ordered state and the crystal symmetry changes to a low-temperature I4/m one. For the specific case of an incommensurate vacancy order at Qv=(1/5, 3/5) in K0.82(2)Fe1.626(3)Se2, we find that it induces a block checkerboard antiferromagnetic phase at wavevector Qm=4 Qv. The coexistence of vacancy order and magnetic order leads to a reconstructed ground state which naturally couples to the d-wave superconductivity in a uniform phase in what we propose will be a general coupling for all iron-selenide superconductors. Our results agree with numerous experimental data available to date. We thus suggest that the incommensurability leads to uniform coexistence of multiple phases as a viable alternative to a nanoscale phase separation in high-Tc superconductors and play an important role in the enhancement of superconductivity.