Thermodynamic evidence for a pressure-driven crossover from strong- to weak-coupling superconductivity in Pb

Abstract

The thermodynamic critical field B c provides direct access to the superconducting condensation energy, yet its pressure dependence has been studied much less extensively than that of the transition temperature. Here, muon-spin-rotation/relaxation measurements of the thermodynamic critical field B c of elemental Pb under hydrostatic pressure up to 2.3 GPa are reported. From the magnetic-field distribution in the intermediate state, B c(T) is determined and B c(0) is extracted at different pressures. In combination with previously reported high-pressure data for B c and T c, it is shown that the pressure dependence of B c(0) follows that of the superconducting gap Δ(0) more closely than that of the transition temperature T c. At higher pressures, the logarithmic pressure derivatives of B c(0) and T c are found to converge, indicating that the coupling strengths ratio α=Δ(0)/k BT c becomes nearly pressure independent. This behavior is interpreted as thermodynamic evidence for a pressure-driven crossover from strong- to weak-coupling superconductivity in Pb.

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