Interference Effects of the Superconducting Pairing Wave Function due to the Fulde-Ferrell-Larkin-Ovchinnikov like State in Ferromagnet/Superconductor Bilayers

TL;DR

This paper investigates the interference effects of the superconducting pairing wave function in ferromagnet/superconductor bilayers, demonstrating critical temperature oscillations and reentrant superconductivity crucial for spin-valve applications.

Contribution

It reports the successful fabrication of F/S bilayers exhibiting deep critical temperature oscillations and reentrant behavior, advancing the understanding of superconducting spin-valve structures.

Findings

Critical temperature oscillations as a function of ferromagnetic layer thickness.

Reentrant superconductivity observed in F/S bilayers.

Large critical temperature shifts between magnetization configurations.

Abstract

The theoretical description of the Fulde-Ferrell-Larkin-Ovchinnikov like state establishing in nanostructered bilayers of ferromagnetic (F) and superconducting (S) material leads to critical temperature oscillations and reentrant superconductivity as the F-layer thickness gradually increases. The experimental realization of these phenomena is an important prerequisite for the fabrication of the Ferromagnet/Superconductor/Ferromagnet core structure of the superconducting spin-valve. A switching of the spin-valve is only expected if such non-monotonic critical temperature behavior is observed in F/S bilayers as well as in the S/F bilayers, a combination of which the spin-valve core structure can be regarded to consist of. In our former investigations we could demonstrate the required non-monotonic behavior of the critical temperature in S/F bilayers. In this study we succeeded in the preparation of F/S bilayers, where the superconducting material is now grown on top of the ferromagnetic metal, which show deep critical temperature oscillations as a function of the ferromagnetic layer thickness as well as an extinction and recovery, i.e. a reentrant behavior, of superconductivity. Especially, the latter is necessary to obtain a spin-valve with a large critical temperature shift between the parallel and antiparallel configurations of magnetizations in the F layers.