Devices or circuits based on spin torque transfer (STT) and Spin Hall effect are disclosed by using a spin Hall effect (SHE) metal layer coupled to a magnetic free layer for various applications. The efficiency or strength of the STT effect based on this combination of SHE and STT can be enhanced by an interface modification between the SHE metal layer and the magnetic free layer or by modifying or engineering the SHE metal layer by doping the SHE metal with certain impurities or other means.

More stable perpendicular magnetization orientation is attained, and switching of the magnetization orientation between an out-of-plane direction and an in-plane direction is enabled by voltage. A multiferroic laminated structure having ferroelectricity and ferromagnetism includes: a ferroelectric layer made of a ferroelectric substance having the ferroelectricity; a foundation layer composed mainly of a metal having a good lattice-matching property with the ferroelectric substance and laminated on a surface of the ferroelectric layer; an intermediate layer composed mainly of a non-magnetic substance and laminated on a surface of the foundation layer; and a ferromagnetic/non-magnetic multilayer film layer constituted by alternately laminating ferromagnetic layers and non-magnetic layers on a surface of the intermediate layer in at least three cycles, the ferromagnetic layers being composed mainly of a ferromagnetic substance, the non-magnetic layers being composed mainly of the non-magnetic substance.

The present invention is directed to an STT-MRAM device comprising a plurality of memory elements. Each of the memory elements includes an MTJ structure that comprises a magnetic free layer structure and a magnetic reference layer structure with an insulating tunnel junction layer interposed therebetween; a first perpendicular enhancement layer (PEL) formed adjacent to the magnetic free layer structure; a magnetic dead layer formed adjacent to the first PEL; and a magnetic fixed layer exchange coupled to the magnetic reference layer structure through an anti-ferromagnetic coupling layer. The magnetic reference layer structure includes a first magnetic reference layer formed adjacent to the insulating tunnel junction layer and a second magnetic reference layer separated from the first magnetic reference layer by a second PEL. The first and second magnetic reference layers have a first invariable magnetization direction substantially perpendicular to layer planes thereof.

A magnetic memory element including first and second magnetic free layers having a variable magnetization direction substantially perpendicular to layer planes thereof; a first perpendicular enhancement layer (PEL) interposed between the first and second magnetic free layers; first and second magnetic reference layers having a first invariable magnetization direction substantially perpendicular to layer planes thereof; a second PEL interposed between the first and second magnetic reference layers; an insulating tunnel junction layer formed between the first magnetic free layer and reference layer; an anti-ferromagnetic coupling layer formed adjacent to the second magnetic reference layer; a magnetic fixed layer formed adjacent to the anti-ferromagnetic coupling layer and having a second invariable magnetization direction substantially opposite to the first invariable magnetization direction; and a cap layer formed adjacent to the second magnetic free layer and comprising iron, oxygen, and a metal element.

Described is an apparatus, for spin state element device, which comprises: a variable resistive magnetic (VRM) device to receive a magnetic control signal to adjust resistance of the VRM device; and a magnetic logic gating (MLG) device, coupled to the VRM device, to receive a magnetic logic input and perform logic operation on the magnetic logic input and to drive an output magnetic signal based on the resistance of the VRM device. Described is a magnetic de-multiplexer which comprises: a first VRM device to receive a magnetic control signal to adjust resistance of the first VRM; a second VRM device to receive the magnetic control signal to adjust resistance of the second VRM device; and an MLG device, coupled to the first and second VRM devices, the MLG device having at least two output magnets to output magnetic signals based on the resistances of the first and second VRM devices.

The present invention is directed to an MRAM element comprising a plurality of magnetic tunnel junction (MTJ) memory elements. Each of the memory elements comprises a magnetic reference layer structure, which includes a first and a second magnetic reference layers with a tantalum perpendicular enhancement layer interposed therebetween, an insulating tunnel junction layer formed adjacent to the first magnetic reference layer opposite the tantalum perpendicular enhancement layer, and a magnetic free layer formed adjacent to the insulating tunnel junction layer. The first and second magnetic reference layers have a first fixed magnetization direction substantially perpendicular to the layer planes thereof.

The present invention is directed to an MRAM element comprising a magnetic free layer structure and a magnetic reference layer structure with an insulating tunnel junction layer interposed therebetween. The magnetic free layer structure has a variable magnetization direction substantially perpendicular to the layer plane thereof. The magnetic reference layer structure includes a first magnetic reference layer formed adjacent to the insulating tunnel junction layer and a second magnetic reference layer separated from the first magnetic reference layer by a first non-magnetic perpendicular enhancement layer. The first and second magnetic reference layers have a first fixed magnetization direction substantially perpendicular to the layer plane thereof. The second magnetic reference layer has a multilayer structure comprising a first magnetic reference sublayer formed adjacent to the first non-magnetic perpendicular enhancement layer and a second magnetic reference sublayer separated from the first magnetic reference sublayer by an intermediate metallic layer.

A data reader may be configured with at least a detector stack positioned on an air bearing surface and consisting of a spin accumulation channel continuously extending from the air bearing surface to an injector stack. The injector stack can have at least one cladding layer contacting the spin accumulation channel. The at least one cladding layer may have a length as measured perpendicular to the ABS that filters minority spins from the detector stack.

A voltage switchable coherent spin field effect transistor is provided by depositing a ferromagnetic base like cobalt on a substrate. A chrome oxide layer is formed on the cobalt by MBE at room at UHV at room temperature. There was thin cobalt oxide interface between the chrome oxide and the cobalt. Other magnetic materials may be employed. A few ML field of graphene is deposited on the chrome oxide by molecular beam epitaxy, and a source and drain are deposited of base material. The resulting device is scalable, provides high on/off rates, is stable and operable at room temperature and easily fabricated with existing technology.

Transition metal dichalcogenide (TMD)-based spintronics devices, each including a TMD thin film layer, a first gate electrode, a first insulating layer sandwiched between the TMD thin film layer and the first gate electrode, a second gate electrode, and a second insulating layer sandwiched between the TMD thin film layer and the second gate electrode. Such a device, when also including a source electrode and a drain electrode, functions as a spin filter. On the other hand, when also including one source electrode and two drain electrode terminals, such a device functions as a spin separator. Also disclosed are methods of using the above-described TMD-based spintronics devices.