Anisotropic multiband superconductivity in 2M-WS2 probed by controlled disorder

Abstract

The intrinsically superconducting Dirac semimetal 2M-WS2 is a promising candidate to realize proximity-induced topological superconductivity in its protected surface states. A precise characterization of the bulk superconducting state is essential for understanding the nature of surface superconductivity in the system. Here, we perform a detailed experimental study of the temperature and nonmagnetic disorder dependence of the London penetration depth λ, the upper critical field Hc2, and the superconducting transition temperature Tc in 2M-WS2. We observe a power-law dependence λ(T) - λ(0) T3 at temperatures below 0.35~Tc, which is remarkably different from the expected exponential attenuation of a fully gapped isotropic s-wave superconductor. We then probe the effect of controlled nonmagnetic disorder induced by 2.5 MeV electron irradiation at various doses and find a significant Tc suppression rate. Together with the observed increase of the slope dHc2/dT|T=Tc with irradiation, our results reveal a strongly anisotropic s++ multiband superconducting state that takes the same sign on different Fermi sheets. Our results have direct consequences for the expected proximity-induced superconductivity of the topological surface states.