Manifestation of triplet superconductivity in superconductor-ferromagnet structures
Abstract
We study proximity effects in a multilayered superconductor/ferromagnet (S/F) structure with arbitrary relative directions of the magnetization M. If the magnetizations of different layers are collinear the superconducting condensate function induced in the F layers has only a singlet component and a triplet one with a zero projection of the total magnetic moment of the Cooper pairs on the M direction. In this case the condensate penetrates the F layers over a short length J determined by the exchange energy J. If the magnetizations M are not collinear the triplet component has, in addition to the zero projection, the projections 1. The latter component is even in the momentum, odd in the Matsubara frequency and penetrates the F layers over a long distance that increases with decreasing temperature and does not depend on J (spin-orbit interaction limits this length). If the thickness of the F layers is much larger than J, the Josephson coupling between neighboring S layers is provided only by the triplet component, so that a new type of superconductivity arises in the transverse direction of the structure. The Josephson critical current is positive (negative) for the case of a positive (negative) chirality of the vector M. We demonstrate that this type of the triplet condensate can be detected also by measuring the density of states in F/S/F structures.
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