Multigap superconductivity in ThAsFeN investigated using muSR measurements

Abstract

We have investigated the superconducting ground state of the newly discovered superconductor ThFeAsN with a tetragonal layered crystal structure using resistivity, magnetization, heat capacity and transverse-field (TF) muon-spin rotation (μSR) measurements. Our resistivity and magnetization measurements reveal an onset of bulk superconductivity with T c 30 K. The heat capacity results show a very small anomaly, ele0.214 (J/mol-K) at T c 30 K and exhibits exponential behavior below T c, which fits better to two superconducting gaps rather than a single gap. Further a nonlinear magnetic field dependence of the electronic specific heat coefficient γ(H) has been found in the low temperature limit, which indicates that the smaller energy gap is nodal. Our analysis of the TF-μSR results shows that the temperature dependence of the superfluid density is better described by a two-gap model either isotropic s+s-wave or s+d-wave than a single gap isotropic s-wave model for the superconducting gap, consistent with other Fe-based superconductors. The combine γ(H) and TF-μSR results confirm s+d-wave model for the gap structure of ThFeAsN. The observation of two gaps in ThFeAsN suggests multiband nature of the superconductivity possibly arising from the d-bands of Fe ions. Furthermore, from our TF-μSR study we have estimated the magnetic penetration depth, in the polycrystalline sample, of λL(0) = 375 nm, superconducting carrier density ns = 4.6 × 1027~ m-3, and carrier's effective-mass m* = 2.205me. We will compare the results of our present study with those reported for the Fe-pnictide family of superconductors.