Critical fields of superconductors with magnetic impurities

Abstract

The upper critical field Hc2 , the field Hc3 for nucleation of the surface superconductivity, and the thermodynamic Hc are evaluated within the weak-coupling theory for the isotropic s-wave case and arbitrary transport and pair-breaking scattering. We find that for the standard geometry of a half-space sample in a magnetic field parallel to the surface, the ratio R=Hc3/Hc2 is within the window 1.55 R 2.34, regardless of temperature, magnetic or non-magnetic scattering. While the non-magnetic impurities tend to flatten the R(T) variation, the magnetic scattering merely shifts the maximum of R(T) to lower temperatures. Surprisingly, while reducing the transition temperature, magnetic scattering has a milder impact on R than the non-magnetic scattering. The surface superconductivity is quite robust; in fact, the ratio R≈ 1.7 even in the gapless state. We used Eilenberger's energy functional to evaluate the condensation energy Fc and the thermodynamic critical field Hc for any temperature and scattering parameters. By comparing Hc2 and Hc, we find that unlike the transport scattering, the pair-breaking pushes materials toward type-I behavior. We find a peculiar behavior of Fc as a function of the pair-breaking scattering parameter at the low-T transition from gapped to gapless phases, which has recently been associated with the topological transition in the superconducting density of states.