The present invention is notably directed to a spin-orbit coupled device. This device comprises a confinement part. It further includes a circuitry, having an input device, energizable to inject spin-polarizations to charge carriers in an input region of the confinement part. The circuitry further comprises an output device, usable to detect spin-polarizations of charge carriers in an output region of the confinement part. The confinement part may be is configured to subject charge carriers drifting therein to a non-linear spin-orbit interaction, which causes to rotate a spin polarization of the drifting charge carriers by an angle that depends non-linearly on momenta of such charge carriers. The circuitry may be configured to allow momenta of charge carriers drifting in the confinement part to be varied, while injecting spin-polarizations in the input region. Varying momenta allows spin-polarizations of drifting charge carriers to be rotated, owing to said non-linear spin-orbit interaction.

The present invention is directed to a spin transfer torque (STT) MRAM device having a perpendicular magnetic tunnel junction (MTJ) memory element. The memory element includes a perpendicular MTJ structure in between a non-magnetic seed layer and a non-magnetic cap layer. The MTJ structure comprises a magnetic free layer structure and a magnetic reference layer structure with an insulating tunnel junction layer interposed therebetween, an anti-ferromagnetic coupling layer formed adjacent to the magnetic reference layer structure, and a magnetic fixed layer formed adjacent to the anti-ferromagnetic coupling layer. At least one of the magnetic free and reference layer structures includes a non-magnetic perpendicular enhancement layer, which improves the perpendicular anisotropy of magnetic layers adjacent thereto.

An embodiment includes a C-element logic gate implemented as a spin logic device that provides a compact and low-power implementation of asynchronous logic by implementing a C-element with spintronic technology. An embodiment includes a first nanopillar including a first contact and a first fixed magnetic layer; a second nanopillar including a second contact and a second fixed magnetic layer; and a third nanopillar including a third contact, a tunnel barrier, and a third fixed magnetic layer; wherein (a) the first, second, and third nanopillars are all formed over a free magnetic layer, and (b) the third fixed magnetic layer, the tunnel barrier, and the free magnetic layer form a magnetic tunnel junction (MTJ). Other embodiments are described herein.

A spin valve element 10 including a spin injector 12 made of a ferromagnetic material, a spin detector 16 made of a ferromagnetic material, and a channel part 14 made of a non-magnetic material. The spin detector 16 is arranged at a position separated from the spin injector 12, the channel part 14 is connected with the spin injector 12 and the spin detector 16 directly or through an insulating layer, and a plurality of spin diffusion portions 30 to 34 with enlarged cross section areas in a direction perpendicular to a spin current is formed in the channel part 14.

Disclosed is a transistor including a topological insulator. The transistor includes: a substrate; a topological insulator provided on the substrate; a drain electrode provided on the topological insulator; a source electrode separated from the drain electrode, provided on the topological insulator, and including a ferromagnetic substance; a tunnel junction layer provided on the source electrode; and a gate electrode provided on the tunnel junction layer. A spin direction of the topological insulator is fixed by a current flowing to a surface thereof, and a spin direction of the source electrode is changed to a predetermined direction by a voltage applied to the gate electrode.

Provided in one embodiment is a device, comprising: a substrate; and a layer disposed over the substrate, wherein the layer comprises a monolayer of crystals comprising a Group IV element.

A spin transport channel includes a dielectric layer contacting a conductive layer. The dielectric layer includes at least one of a tantalum oxide, hafnium oxide, titanium oxide, and nickel oxide. An intermediate spin layer contacts the dielectric layer. The intermediate spin layer includes at least one of copper and silver. The conductive layer is more electrochemically inert than the intermediate spin layer. A polarizer layer contacts the intermediate spin layer. The polarizer layer includes one of a nickel-iron based material, iron, and cobalt based material. The conductive layer and intermediate layer are disposed on opposite sides of the dielectric layer. The dielectric layer and the polarizer layer are disposed on opposite sides of the intermediate spin layer. The intermediate spin layer is arranged to form a conducting path through the dielectric layer configured to transport a plurality of electrons. Each of the plurality of electrons maintains a polarized electron spin.

The present invention is directed to a spin transfer torque (STT) MRAM device having a perpendicular magnetic tunnel junction (MTJ) memory element. The memory element includes a perpendicular MTJ structure in between a non-magnetic seed layer and a non-magnetic cap layer. The MTJ structure comprises a magnetic free layer structure and a magnetic reference layer structure with an insulating tunnel junction layer interposed therebetween, an anti-ferromagnetic coupling layer formed adjacent to the magnetic reference layer structure, and a magnetic fixed layer formed adjacent to the anti-ferromagnetic coupling layer. At least one of the magnetic free and reference layer structures includes a non-magnetic perpendicular enhancement layer, which improves the perpendicular anisotropy of magnetic layers adjacent thereto.

A spin rotary member includes a substrate, a spin injector made of a ferromagnetic material magnetized in a substrate in-plane direction, and provided on the substrate, a spin rotor made of a ferromagnetic material having a magnetic moment rotatable in the substrate in-plane direction, and provided on the substrate, being separated from the spin injector, a channel part made of a non-magnetic material, arranged between the spin injector and the spin rotor, and bonded with the spin injector and the spin rotor directly or through an insulating layer, and a spin rotation control part configured to control a rotation direction of spin of the channel part.

The present invention is directed to an MTJ memory element including a magnetic free layer structure which comprises one or more magnetic free layers that have a same variable magnetization direction substantially perpendicular to layer planes thereof; an insulating tunnel junction layer formed adjacent to the magnetic free layer structure; a magnetic reference layer structure comprising a first magnetic reference layer formed adjacent to the insulating tunnel junction layer and a second magnetic reference layer separated therefrom by a perpendicular enhancement layer with the first and second magnetic reference layers having a first fixed magnetization direction substantially perpendicular to layer planes thereof; an anti-ferromagnetic coupling layer formed adjacent to the second magnetic reference layer opposite the perpendicular enhancement layer; and a magnetic fixed layer comprising first and second magnetic fixed sublayers with the second magnetic fixed sublayer formed adjacent to the anti-ferromagnetic coupling layer opposite the second magnetic reference layer.