A memory structure comprises a dielectric layer, a first ferromagnetic bottom electrode, a second ferromagnetic bottom electrode, an SOT channel layer, and an MTJ structure. The dielectric layer is over the substrate. The first ferromagnetic bottom electrode extends through the dielectric layer. The second ferromagnetic bottom electrode extends through the dielectric layer, and is spaced apart from the first ferromagnetic bottom electrode. The SOT channel layer extends from the first ferromagnetic bottom electrode to the second ferromagnetic bottom electrode. The MTJ structure is over the SOT channel layer.

A magnetic tunneling junction (MTJ) device structure and the method of constructing such device are disclosed. Also disclosed are methods of using the device for spin-dependent transport characterization through biomolecules for structure and dynamic function analysis in physiological environments.

A magnetic tunneling junction (MTJ) device structure and the method of constructing such device are disclosed. Also disclosed are methods of using the device for spin-dependent transport characterization through biomolecules for structure and dynamic function analysis in physiological environments.

Provided is a cache memory, including: a first field-effect transistor, a field-like spin torque layer underneath a magnetic tunnel junction, an electrode, and a second field-effect transistor sequentially arranged and connected; wherein the first field-effect transistor is configured to provide a writing current and to control the on-off of the writing current through a gate electrode; the field-like spin torque layer is configured to generate field-like spin torques for switching a first ferromagnetic layer of the magnetic tunnel junction; the magnetic tunnel junction includes a first ferromagnetic layer, a tunneling layer, a second ferromagnetic layer and a pinning layer arranged sequentially; the electrode is configured to connect the cache memory with the second field-effect transistor; and the second field-effect transistor is configured to control the on-off of the second field-effect transistor through the gate electrode to read the resistive state of the magnetic tunnel junction.

Provided is a cache memory, including: a first field-effect transistor, a field-like spin torque layer underneath a magnetic tunnel junction, an electrode, and a second field-effect transistor sequentially arranged and connected; wherein the first field-effect transistor is configured to provide a writing current and to control the on-off of the writing current through a gate electrode; the field-like spin torque layer is configured to generate field-like spin torques for switching a first ferromagnetic layer of the magnetic tunnel junction; the magnetic tunnel junction includes a first ferromagnetic layer, a tunneling layer, a second ferromagnetic layer and a pinning layer arranged sequentially; the electrode is configured to connect the cache memory with the second field-effect transistor; and the second field-effect transistor is configured to control the on-off of the second field-effect transistor through the gate electrode to read the resistive state of the magnetic tunnel junction.

Devices for sensing and manipulating magnetic fields based on spin current interactions independent of the Spin Hall Effect (SHE) in heavy metal. Spin current is generated in ordinary metals by conversion of out-of-plane orbital current arising from the Orbital Hall Effect (OHE). The conversion from orbital current to spin current takes place in a thin layer of heavy metal (several atomic layers thick), thereby substantially reducing heavy metal requirements by replacing heavy metal with ordinary metal. Device applications include magnetoresistive sensors for detecting and measuring magnetic fields, and magnetic tunnel junction data storage units.

Devices for sensing and manipulating magnetic fields based on spin current interactions independent of the Spin Hall Effect (SHE) in heavy metal. Spin current is generated in ordinary metals by conversion of out-of-plane orbital current arising from the Orbital Hall Effect (OHE). The conversion from orbital current to spin current takes place in a thin layer of heavy metal (several atomic layers thick), thereby substantially reducing heavy metal requirements by replacing heavy metal with ordinary metal. Device applications include magnetoresistive sensors for detecting and measuring magnetic fields, and magnetic tunnel junction data storage units.

A layer including a topological insulator, the layer including: an arrangement of a plurality of patterns on a surface of the layer, each pattern of the plurality of patterns including at least a non-straight elongated portion. An electronic device including the layer including a topological insulator, and further including first and second electrodes on the layer. Further, the first and second electrodes may be configured to provide electrical connection to the layer. A method of controlling spin transport in the layer includes a topological insulator, the method including: applying circularly polarized light on the layer; and driving an electronic component with a photocurrent produced in the layer by the circularly polarized light.

A layer including a topological insulator, the layer including: an arrangement of a plurality of patterns on a surface of the layer, each pattern of the plurality of patterns including at least a non-straight elongated portion. An electronic device including the layer including a topological insulator, and further including first and second electrodes on the layer. Further, the first and second electrodes may be configured to provide electrical connection to the layer. A method of controlling spin transport in the layer includes a topological insulator, the method including: applying circularly polarized light on the layer; and driving an electronic component with a photocurrent produced in the layer by the circularly polarized light.

An SOT-driven field-free switching MRAM and an array thereof. From top to bottom, the SOT-MRAM sequentially includes: a selector (1) configured to turn on or turn off the SOT-MRAM under an action of an external voltage; a magnetic tunnel junction (2), including a ferromagnetic reference layer, a tunneling layer and a ferromagnetic free layer arranged sequentially from top to bottom; and a spin-orbit coupling layer (3) made of one or more selected from heavy metal, doped heavy metal, heavy metal alloy, metal oxide, dual heavy metal layers, semiconductor material, two-dimensional semi-metal material and anti-ferromagnetic material. The spin-orbit coupling layer is configured to generate an in-plane effective field in the ferromagnetic free layer by using the interlayer exchange coupling effect and generate spin-orbit torques by using the spin Hall effect, so as to perform a deterministic data storage in the magnetic tunnel junction (2).