Odd spin-triplet superconductivity in a multilayered superconductor-ferromagnet Josephson junction

Abstract

We study the dc Josephson effect in a diffusive multilayered SF'FF'S structure, where S is a superconductor and F,F' are different ferromagnets. We assume that the exchange energies in the F' and F layers are different (% h and H, respectively) and the middle F layer consists of two layers with parallel or antiparallel magnetization vectors M. The M vectors in the left and right F' layers are generally not collinear to those in the F layer. In the limit of a weak proximity effect we use a linearized Usadel equation. Solving this equation, we calculate the Josephson critical current for arbitrary temperatures, arbitrary thicknesses of the F' and F layers (% Lh and LH) in the case of parallel and antiparallel M orientations in the F layer. The part of the critical current IcSR formed by the short-range (SRC) singlet and S=0 triplet condensate components decays on a short length H=D/H, whereas the part % IcLR due to the long-range triplet |S|=1 component (LRTC) decreases with increasing LH on the length N=D/π T. Our results are in agreement with the experiment Birge.