Superconducting spin valve effect in the Co/Pb/Co heterostructure with insulating interlayers
Abstract
We report the superconducting properties of the Co/Pb/Co heterostructures with thin insulating interlayers. The main specific feature of these structures is the intentional oxidation of both superconductor/ferromagnet (S/F) interfaces. We study variation of the critical temperature of our systems due to switching between parallel and antiparallel configurations of the magnetizations of the two magnetic layers. Common wisdom suggests that this spin valve effect, which is due to the S/F proximity effect, is most pronounced in the case of perfect metallic contact at the interfaces. Nevertheless, in our structures with intentionally deteriorated interfaces, we observed a significant full spin valve effect. A shift of the superconducting transition temperature Tc by switching the mutual orientation of the magnetizations of the two ferromagnetic Co layers from antiparallel to parallel amounted to Tc =0.2 K at the optimal thickness of the superconducting Pb layer. Our finding verifies the so far unconfirmed earlier results by Deutscher and Meunier on an F1/S/F2 heterostructure with oxidized interlayers [https://doi.org/10.1103/PhysRevLett.22.395, G. Deutscher and F. Meunier, Phys. Rev. Lett. 22, 395 (1969)] and suggests an alternative route to optimize the performance of the superconducting spin valves.
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