Proximity Effect in a Superconducting Triplet Spin Valve S1/F1/S2/F2

Gaifullin, R.R.; Kushnir, V. N.; Деминов, Р. Г.; Тагиров, Л. Р.; Kupriyanov, M. Yu.; Golubov, A. A.

doi:10.1134/s1063783419090063

Phys. Solid State

2019

DOI: 10.1134/s1063783419090063

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Proximity Effect in a Superconducting Triplet Spin Valve S1/F1/S2/F2

R.R. Gaifullin

V. N. Kushnir

Р. Г. Деминов

et al.

Abstract: С помощью матричного метода решения линеаризованных уравнений Узаделя получены критические температуры многослойных структур вида сверхпроводник / ферромагнетик / ферромагнетик (S/F/F). Рассмотрено влияние дополнительного слоя сверхпроводника на эффекты трехслойного спинового вентиля. В сравнении с дополнительным нормальным слоем в структуре S/F/N/F, обсуждена возможность увеличения эффективности режимов спинового вентиля с дополнительным сверхпроводящим слоем S на месте слоя N.

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Cited by 6 publications

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“…Contact between a superconductor (S) and a ferromagnetic metal (F) is very attractive for investigations because of the possible coexistence of ferromagnetic and superconducting orders in the same sample [1][2][3][4][5][6][7]. The possibility of applying these systems in superconducting microelectronics was investigated theoretically and experimentally [8][9][10].…”

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confidence: 99%

“…In the generalized Kupriyanov-Lukichev boundary conditions [25], the gradient is also replaced with the extended derivative. For example, we present the boundary conditions for a two-layer S/F system: (6) where is the Fermi velocity in the S (F) layer and σ s(f) is the boundary transparency from the side of the S (F) layer [3]. In this case, the normal is directed from the S layer to the F layer.…”

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confidence: 99%

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Critical Temperature of a Superconductor/Ferromagnet Nanostructure near a Magnetic Skyrmion

2022

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Contact between a superconductor and a chiral ferromagnet containing complex magnetic structures (helical or conical texture, skyrmion, and chiral float) has been considered. The case of a single skyrmion has been studied more thoroughly. The influence of these magnetic inhomogeneities on the critical temperature becomes significant only for nanoscale spin structures (about 100 nm or smaller). Skyrmion lattices and single skyrmions of such sizes have recently been observed in experiments with thin magnetic layers. Within the proximity effect theory in the dirty limit, an approximate approach has been proposed to calculate the critical temperature in these systems. Great influence of nanoscale spin vortices on the critical temperature, in combination with topological stability and a low current density that is necessary for their motion, makes it possible to use these systems as efficient superconducting spin valves.

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confidence: 99%

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Critical Temperature of a Superconductor/Ferromagnet Nanostructure near a Magnetic Skyrmion

2022

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Magnonic control of the superconducting spin valve by magnetization reorientation in a helimagnet

Гусев

Dgheparov

Pugach

et al. 2021

Applied Physics Letters

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We propose a method to control a bilayer superconducting spin valve (SSV) which does not perturb its superconducting state and is suitable for energy saving cryogenic electronics. This SSV consists of a superconducting layer and a helimagnetic layer of B20 family compounds, namely, Nb and spiral antiferromagnet MnSi. Thanks to unique properties of MnSi—broken inversion symmetry and cubic crystal lattice—there are a few ground state magnetic configurations with different directions of the magnetic spiral, divided by a potential barrier. Superconductivity in such a bilayer is controlled by the reorientation of the spiral vector in the MnSi layer, which leads to a change in the critical temperature of the Nb layer due to the proximity effect. The switching is proposed to be carried out by a several hundred ps in duration magnetic field pulse of several kOe in magnitude. Such a pulse does not destroy the superconducting state of the Nb layer by itself but leads to the excitation of magnons in the MnSi layer, which triggers the reorientation process of the magnetic spiral. After the completion of this process, the Nb layer switches into a normal state. Inverse switching returns the spiral to the initial state, opening the valve and turning on the superconducting state. The system can be switched there and back by a magnetic field of opposite signs along one direction in the layers plane, which allows an easy control. The switching time is estimated as several nanoseconds, which coincides with the scales of the STT-MRAM recording time.

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Controllаble Josephson 0–π Junction Based on a Four-Layer Ferromagnetic–Superconductor System (FSFS)

Borisova

Tumanov

Proshin

2020

Phys. Metals Metallogr.

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Proximity Effect in a Superconducting Triplet Spin Valve S1/F1/S2/F2

Cited by 6 publications

References 6 publications

Critical Temperature of a Superconductor/Ferromagnet Nanostructure near a Magnetic Skyrmion

Critical Temperature of a Superconductor/Ferromagnet Nanostructure near a Magnetic Skyrmion

Magnonic control of the superconducting spin valve by magnetization reorientation in a helimagnet

Controllаble Josephson 0–π Junction Based on a Four-Layer Ferromagnetic–Superconductor System (FSFS)

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