Theory of proximity effect in superconductor/ferromagnet heterostructures
Abstract
We present a microscopic theory of proximity effect in the ferromagnet/superconductor/ferromagnet (F/S/F) nanostructures where S is s-wave low-Tc superconductor and F's are layers of 3d transition ferromagnetic metal. Our approach is based on the solution of Gor'kov equations for the normal and anomalous Green's functions together with a self-consistent evaluation of the superconducting order parameter. We take into account the elastic spin-conserving scattering of the electrons assuming s-wave scattering in the S layer and s-d scattering in the F layers. In accordance with the previous quasiclassical theories, we found that due to exchange field in the ferromagnet the anomalous Green's function F(z) exhibits the damping oscillations in the F-layer as a function of distance z from the S/F interface. In the given model a half of period of oscillations is determined by the length m0 = π vF/Eex, where vF is the Fermi velocity and Eex is the exchange field, while damping is governed by the length l0 = (1/l + 1/l)-1 with l and l being spin-dependent mean free paths in the ferromagnet. The superconducting transition temperature Tc(dF) of the F/S/F trilayer shows the damping oscillations as a function of the F-layer thickness dF with period F = π/m Eex, where m is the effective electron mass. We show that strong spin-conserving scattering either in the superconductor or in the ferromagnet significantly suppresses these oscillations. The calculated Tc(dF) dependences are compared with existing experimental data for Fe/Nb/Fe trilayers and Nb/Co multilayers.
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