Strong- to weak-coupling superconductivity in high-Tc bismuthates: revisiting the phase diagram via μSR

Abstract

Several decades after the discovery of superconductivity in bismuthates, the strength of their electron-phonon coupling and its evolution with doping remain puzzling. To clarify these issues, polycrystalline hole-doped Ba1-xKxBiO3 (0.1 x 0.6) samples were systematically synthesized and their bulk- and microscopic superconducting properties were investigated by means of magnetic susceptibility and muon-spin rotation/relaxation (μSR), respectively. The phase diagram of Ba1-xKxBiO3 was reliably extended up to x = 0.6, which is still found to be a bulk superconductor. The lattice parameter a increases linearly with K-content, implying a homogeneous chemical doping. The low-temperature superfluid density, measured via transverse-field (TF)-μSR, indicates an isotropic fully-gapped superconducting state with zero-temperature gaps 0/kBTc = 2.15, 2.10, and 1.75, and magnetic penetration depths λ0 = 219, 184, and 279 nm for x = 0.3, 0.4, and 0.6, respectively. A change in the superconducting gap, from a nearly ideal BCS value (1.76 kBTc in the weak coupling case) in the overdoped x = 0.6 region, to much higher values in the optimally-doped case, implies a gradual decrease in electron-phonon coupling with doping.