Self-consistent two-gap approach in studying multi-band superconductivity in NdFeAsO0.65F0.35

Abstract

High-quality single crystals of NdFeAsO0.65F0.35 (the transition temperature T c 30.6~K) were studied in zero-field (ZF) and transverse-field (TF) muon-spin rotation/relaxation (μSR) experiments. An upturn in muon-spin depolarization rate at T 3~K was observed in ZF-μSR measurements and it was associated with the onset of ordering of Nd electronic moments. Measurements of the magnetic field penetration depth (λ) were performed in the TF geometry. By applying the external magnetic field B ex parallel to the crystallographic c-axis (B ex\| c) and parallel to the ab-plane (B ex\| ab), the temperature dependencies of the in-plane component (λab-2) and the combination of the in-plane and the out of plane components (λab,c-2) of the superfluid density were determined, respectively. The out-of-plane superfluid density component (λc-2) was further obtained by combining the results of B ex \| c and B ex \| ab set of experiments. The temperature dependencies of λab-2, λab,c-2, and λc-2 were analyzed within the framework of a self-consistent two-gap model despite of using the traditional α-model. Interband coupling was taken into account, instead of assuming it to be zero as it stated in the α-model. A relatively small value of the interband coupling constant 12 0.01 was obtained, thus indicating that the energy bands in NdFeAsO0.65F0.35 are only weakly coupled. In spite of their small magnitude, the coupling between the bands leads to the single value of the superconducting transition temperature T c.