Novel Anisotropy of Upper Critical Fields in Fe1+yTe0.6Se0.4

Abstract

Studying the upper critical field (μ0Hc2) and its anisotropy of superconductors is of great importance because it can provide an unusual insight into the pair-breaking mechanism. Since Fe1+yTe1-xSex exhibits the high μ0Hc2 and small anisotropic superconductivity, it has attracted considerable attention. However, some issues related to μ0Hc2 are still unknown, including the effect of excess Fe content on μ0Hc2 behavior and the origin of the crossover of the μ0Hc2c -- T and μ0Hc2ab -- T curves. In this work, the value of μ0Hc2 of Fe1+yTe0.6Se0.4 single crystals with controlled amounts of excess Fe was obtained by resistivity measurements over a wide range of temperatures down to 1.5 K, and magnetic fields up to 60 T. The crossover of the μ0Hc2c -- T and μ0Hc2ab -- T curves was found to be independent of the excess Fe content. The angle dependence of μ0Hc2 was also checked. The μ0Hc2(θ) symmetry at higher temperature near Tc could be fitted by anisotropic G-L model, and novel fourfold symmetry of μ0Hc2 at lower temperature was found. Based on our spin-locking pairing model, the crossover behavior originates from the anisotropic spin-paramagnetic effect, and the novel fourfold symmetry of μ0Hc2 could be understood by our extended anisotropic G-L model.