Weak Interband-Coupling Superconductivity in the Filled Skutterudite LaPt4Ge12

Abstract

The superconducting pairing state of LaPt4Ge12 is studied by measuring the magnetic penetration depth λ(T,B) and the superfluid density s(T) using a tunnel-diode-oscillator (TDO)-based method and by transverse field muon-spin rotation (μSR) spectroscopy. λ(T) follows an exponential-type temperature dependence at T Tc, but its zero-temperature value λ(0) increases linearly with magnetic field. Detailed analyses demonstrate that both λ(T) and the corresponding s(T), measured in the Meissner state by the TDO method are well described by a two-gap γ model with gap sizes of 1(0)=1.31kBTc and 2(0)=1.80kBTc and a very weak interband coupling. In contrast, s(T), derived from the μ SR data taken in a small field, can be fitted by a single-gap BCS model with a gap close to 2(0). We conclude that LaPt4Ge12 is a marginal two-gap superconductor and the small gap 1 seems to be destroyed by a small magnetic field. In comparison, in PrPt4Ge12 the 4f-electrons may enhance the interband coupling and, therefore, give rise to more robust multiband superconductivity.