We study the critical temperature T_c of SFF trilayers (S is a singlet
superconductor, F is a ferromagnetic metal), where the long-range triplet
superconducting component is generated at noncollinear magnetizations of the F
layers. We demonstrate that T_c can be a nonmonotonic function of the angle
\alpha between the magnetizations of the two F layers. The minimum is achieved
at an intermediate \alpha, lying between the parallel (P, \alpha=0) and
antiparallel (AP, \alpha=\pi) cases. This implies a possibility of a "triplet"
spin-valve effect: at temperatures above the minimum T_c^{Tr} but below T_c^{P}
and T_c^{AP}, the system is superconducting only in the vicinity of the
collinear orientations. At certain parameters, we predict a reentrant
T_c(\alpha) behavior. At the same time, considering only the P and AP
orientations, we find that both the "standard" (T_c^{P} < T_c^{AP}) and
"inverse" (T_c^{P} > T_c^{AP}) switching effects are possible depending on
parameters of the system.Comment: 5 pages (including 4 EPS figures
A quasiclassical theory of giant magnetoresistance in nanoscale point contacts between different ferromagnetic metals is developed. The contacts were sorted by three types of mutual positions of the conduction spin-subband bottoms which are shifted one against another by the exchange interaction. A model of linear domain wall has been used to account for the finite contact length. The magnetoresistance is plotted against the size of the nanocontact. In heterocontacts the magnetoresistance effect turned out to be not only negative, as usual, but can be positive as well. Relevance of the results to existing experiments on GMR in point heterocontacts is discussed.
Summary
Background: In nanoscale layered S/F1/N/F2/AF heterostructures, the generation of a long-range, odd-in-frequency spin-projection one triplet component of superconductivity, arising at non-collinear alignment of the magnetizations of F1 and F2, exhausts the singlet state. This yields the possibility of a global minimum of the superconducting transition temperature T
c, i.e., a superconducting triplet spin-valve effect, around mutually perpendicular alignment.
Results: The superconducting triplet spin valve is realized with S = Nb a singlet superconductor, F1 = Cu41Ni59 and F2 = Co ferromagnetic metals, AF = CoOx an antiferromagnetic oxide, and N = nc-Nb a normal conducting (nc) non-magnetic metal, which serves to decouple F1 and F2. The non-collinear alignment of the magnetizations is obtained by applying an external magnetic field parallel to the layers of the heterostructure and exploiting the intrinsic perpendicular easy-axis of the magnetization of the Cu41Ni59 thin film in conjunction with the exchange bias between CoOx and Co. The magnetic configurations are confirmed by superconducting quantum interference device (SQUID) magnetic moment measurements. The triplet spin-valve effect has been investigated for different layer thicknesses, d
F1, of F1 and was found to decay with increasing d
F1. The data is described by an empirical model and, moreover, by calculations using the microscopic theory.
Conclusion: The long-range triplet component of superconducting pairing is generated from the singlet component mainly at the N/F2 interface, where the amplitude of the singlet component is suppressed exponentially with increasing distance d
F1. The decay length of the empirical model is found to be comparable to twice the electron mean free path of F1 and, thus, to the decay length of the singlet component in F1. Moreover, the obtained data is in qualitative agreement with the microscopic theory, which, however, predicts a (not investigated) breakdown of the triplet spin-valve effect for d
F1 smaller than 0.3 to 0.4 times the magnetic coherence length, ξF1.
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