Interface transparency of superconductor/ferromagnetic multilayers

We have investigated the behavior of the superconducting transition temperature T_c in superconducting/ferromagnetic (S/F) multilayers, as a function of the different layer thicknesses and for varying magnetic moment μ_F of the F-layer atoms. The system studied consists of superconducting V and ferromagnetic V_1-xFe_x alloys with x such that μ_F on the Fe atom is varied between 2 and 0.25μ_B. We determined the superconducting coherence length in the F layer ξ_F, which is found to be inversely proportional to μ_F. We also determined the critical thickness of the S layer, above which superconductivity appears. This thickness is found to be strongly nonmonotonic as function of the Fe concentration in the alloys. By analyzing the data in terms of the proximity-effect theory, we show that with increasing μ_F, the increasing pair breaking in the F layer by the exchange field is counteracted by a decreasing transparency of the S/F interface for Cooper pairs.