Unconventional nodal superconductivity in miassite Rh17S15

Abstract

Unconventional superconductivity has long been believed to arise from a lab-grown correlated electronic system. Here we report compelling evidence of unconventional nodal superconductivity in a mineral superconductor . We investigated the temperature-dependent London penetration depth λ(T) and disorder evolution of the critical temperature Tc and upper critical field Hc2(T) in synthetic miassite . We found a power-law behavior of λ(T) Tn with n≈ 1.1 at low temperatures below 0.3Tc (Tc = 5.4 K), which is consistent with the presence of lines of the node in the superconducting gap of . The nodal character of the superconducting state in ~was supported by the observed pairbreaking effect in Tc and Hc2(T) in samples with the controlled disorder that was introduced by low-temperature electron irradiation. We propose a nodal sign-changing superconducting gap in the A1g irreducible representation, which preserves the cubic symmetry of the crystal and is in excellent agreement with the superfluid density, λ2(0)/λ2(T).