Probing the superconducting pairing of the La4Be33Pt16 alloy via muon-spin spectroscopy
Abstract
We report a study of the superconducting pairing of the noncentrosymmetric La4Be33Pt16 alloy using muon-spin rotation and relaxation (μSR) technique. Below Tc = 2.4 K, La4Be33Pt16 exhibits bulk superconductivity (SC), here characterized by heat-capacity and magnetic-susceptibility measurements. The temperature dependence of the superfluid density sc(T), extracted from the transverse-field SR measurements, reveals a nodeless SC in La4Be33Pt16. The best fit of sc(T) using an s-wave model yields a magnetic penetration depth λ0 = 542 nm and a superconducting gap 0 = 0.37 meV at zero Kelvin. The single-gapped superconducting state is further evidenced by the temperature-dependent electronic specific heat Ce(T)/T and the linear field-dependent electronic specific-heat coefficient γH(H). The zero-field μSR spectra collected in the normal- and superconducting states of La4Be33Pt16 are almost identical, confirming the absence of an additional field-related relaxation and, thus, of spontaneous magnetic fields below Tc. The nodeless SC combined with a preserved time-reversal symmetry in the superconducting state prove that the spin-singlet pairing is dominant in La4Be33Pt16. This material represents yet another example of a complex system showing only a conventional behavior, in spite of a noncentrosymmetric structure and a sizeable spin-orbit coupling.
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