Your search keyword '"Ouassou, Jabir Ali"' showing total 5 results

1. Controlling supercurrents and their spatial distribution in ferromagnets.

Author

Lahabi, Kaveh, Beukers, Ewout, Pleijster, Menno, Aarts, Jan, Amundsen, Morten, Ouassou, Jabir Ali, Linder, Jacob, and Alkemade, Paul

Subjects

FERROMAGNETIC materials, SUPERCONDUCTORS, SPINTRONICS, MAGNETIZATION, INTERFEROMETRY

Abstract

Spin-triplet Cooper pairs induced in ferromagnets form the centrepiece of the emerging field of superconducting spintronics. Usually the focus is on the spin-polarization of the triplets, potentially enabling low-dissipation magnetization switching. However, the magnetic texture which provides the fundamental mechanism for generating triplets also permits control over the spatial distribution of supercurrent. Here we demonstrate the tailoring of distinct supercurrent pathways in the ferromagnetic barrier of a Josephson junction. We combine micromagnetic simulations with three-dimensional supercurrent calculations to design a diskshaped structure with a ferromagnetic vortex which induces two transport channels across the junction. By using superconducting quantum interferometry, we show the existence of two channels. Moreover, we show how the supercurrent can be controlled by moving the vortex with a magnetic field. This approach paves the way for supercurrent paths to be dynamically reconfigured in order to switch between different functionalities in the same device. [ABSTRACT FROM AUTHOR]

Published

2017

2. Controlling spin supercurrents via nonequilibrium spin injection.

Author

Ouassou, Jabir Ali, Robinson, Jason W. A., and Linder, Jacob

Subjects

*SUPERCONDUCTORS, *FERROMAGNETIC materials, *SPINTRONICS, *MAGNETIC control, *QUASIPARTICLES

Abstract

We propose a mechanism whereby spin supercurrents can be manipulated in superconductor/ferromagnet proximity systems via nonequilibrium spin injection. We find that if a spin supercurrent exists in equilibrium, a nonequilibrium spin accumulation will exert a torque on the spins transported by this current. This interaction causes a new spin supercurrent contribution to manifest out of equilibrium, which is proportional to and polarized perpendicularly to both the injected spins and the equilibrium spin current. This is interesting for several reasons: as a fundamental physical effect; due to possible applications as a way to control spin supercurrents; and timeliness in light of recent experiments on spin injection in proximitized superconductors. [ABSTRACT FROM AUTHOR]

Published

2019

3. Analytically determined topological phase diagram of the proximity-induced gap in diffusive n-terminal Josephson junctions.

Author

Amundsen, Morten, Ouassou, Jabir Ali, and Linder, Jacob

Abstract

Multiterminal Josephson junctions have recently been proposed as a route to artificially mimic topological matter with the distinct advantage that its properties can be controlled via the superconducting phase difference, giving rise to Weyl points in 4-terminal geometries. A key goal is to accurately determine when the system makes a transition from a gapped to non-gapped state as a function of the phase differences in the system, the latter effectively playing the role of quasiparticle momenta in conventional topological matter. We here determine the proximity gap phase diagram of diffusive n-terminal Josephson junctions (), both numerically and analytically, by identifying a class of solutions to the Usadel equation at zero energy in the full proximity effect regime. We present an analytical equation which provides the phase diagram for an arbitrary number of terminals n. After briefly demonstrating the validity of the analytical approach in the previously studied 2- and 3-terminal cases, we focus on the 4-terminal case and map out the regimes where the electronic excitations in the system are gapped and non-gapped, respectively, demonstrating also in this case full agreement between the analytical and numerical approach. [ABSTRACT FROM AUTHOR]

Published

2017

4. Microwave control of the superconducting proximity effect and minigap in magnetic and normal metals.

Author

Linder, Jacob, Amundsen, Morten, and Ouassou, Jabir Ali

Abstract

We demonstrate theoretically that microwave radiation applied to superconducting proximity structures controls the minigap and other spectral features in the density of states of normal and magnetic metals, respectively. Considering both a bilayer and Josephson junction geometry, we show that microwaves with frequency ω qualitatively alters the spectral properties of the system: inducing a series of resonances, controlling the minigap size Emg, and even replacing the minigap with a strong peak of quasiparticle accumulation at zero energy when ω = Emg. The interaction between light and Cooper pairs may thus open a route to active control of quantum coherent phenomena in superconducting proximity structures. [ABSTRACT FROM AUTHOR]

Published

2016

5. Electric control of superconducting transition through a spin-orbit coupled interface.

Author

Ouassou, Jabir Ali, Di Bernardo, Angelo, Robinson, Jason W. A., and Linder, Jacob

Published

2016