A current sensor package, comprises a current path and a sensing device. The sensing device is spaced from the current path, and the sensing device is configured for sensing a magnetic field generated by a current flowing through the current path. Further, the sensing device comprises a sensor element. The sensing device is electrically connected to a conductive trace. An encapsulant extends continuously between the current path and the sensing device.

A spin element includes a wiring, a laminated body including a first ferromagnetic layer laminated on the wiring, a first conductive part and a second conductive part which sandwich the first ferromagnetic layer in a plan view in a laminating direction, and a first high resistance layer which is in contact with the wiring between the first conductive part and the wiring and has an electrical resistivity equal to or higher than that of the wiring.

The present invention relates to a semiconductor device. The semiconductor device based on the spin orbit torque (SOT) effect, according to an example of the present invention, comprises the first electrode; and the first cell and the second cell connected to the first electrode, wherein the first and the second cells are arranged on the first electrode separately; the magnetic tunnel junction (MTJ) having a free magnetic layer and a pinned magnetic layer with a dielectric layer in between them; the magnetization direction of the free magnetic layer is changed when the current applied on the first electrode exceeds critical current value of each cell; and the critical current value of the first cell is different from that of the second cell.

The magnetic memory element (100) includes: a conductive layer that includes a heavy metal layer (10) containing a 5d transition metal; a first ferromagnetic layer (20) that is adjacent to the conductive layer and contains a ferromagnetic layer having a reversible magnetization; a barrier layer (30) that is adjacent to the first ferromagnetic layer (20) and includes an insulating material; a reference layer (40) that is adjacent to the barrier layer (30) and has at least one second ferromagnetic layer (41) having a fixed magnetization direction; a cap layer (50) that is adjacent to the reference layer (40) and includes a conductive material; a first terminal (T1) that is capable of introducing a current into one end of the heavy metal layer (10) in the longitudinal direction; a second terminal (T2) that is capable of introducing a current into the other end of the heavy metal layer (10) in the longitudinal direction; and a third terminal (T3) that is capable of introducing a current into the cap layer (50).

A magnetic random access memory assisted non-volatile Hall effect device includes a spin orbit torque layer disposed over a substrate, and a magnetic layer disposed over the spin orbit torque layer. A metal oxide layer disposed over the magnetic layer. Portions of the spin orbit torque layer extend outward from the magnetic layer and the metal oxide layer on opposing sides of a first direction and opposing sides of a second direction in plan view, and the second direction is perpendicular to the first direction.

A magnetic device includes a layer stack comprising a first ferromagnetic layer; a spacer layer on the first ferromagnetic layer; a second ferromagnetic layer on the spacer layer; a dielectric barrier layer on the second ferromagnetic layer; an insertion layer positioned between the second ferromagnetic layer and the dielectric barrier layer; and a fixed layer or an electrode on the dielectric barrier layer. In some examples, a magnetic orientation of the second ferromagnetic layer is switched by a bias voltage across the layer stack without application of an external magnetic field; an antiferromagnetic coupling of the first and second ferromagnetic layers is increased by the bias voltage applying a negative charge to the fixed layer or the electrode, and the antiferromagnetic coupling of the first and second ferromagnetic layers is decreased by the bias voltage applying a positive charge to the fixed layer or the electrode.

A method of manufacturing a magnetoresistive device may comprise forming a first magnetic region, an intermediate region, and a second magnetic region of a magnetoresistive stack above a via; removing at least a portion of the second magnetic region using a first etch; removing at least a portion of the intermediate region and at least a portion of the first magnetic region using a second etch; removing at least a portion of material redeposited on the magnetoresistive stack using a third etch; and rendering at least a portion of the redeposited material remaining on the magnetoresistive stack electrically non-conductive.

The magnetization rotation element includes: a spin-orbit torque wiring; and a first ferromagnetic layer which is stacked on the spin-orbit torque wiring, wherein the spin-orbit torque wiring includes a plurality of wiring layers, and wherein, in a cross section orthogonal to a length direction of the spin-orbit torque wiring, a product between a cross-sectional area and a resistivity of each of the wiring layers is larger in the wiring layer closer to the first ferromagnetic layer.

A memory device may comprise a substrate defining a main plane; a plurality of memory cells each comprising a SOT current layer disposed in the main plane of the substrate and a magnetic tunnel junction residing on the SOT current layer; and a bit line and a source line to flow a write current in a write path including the SOT current layer of a selected memory cell. The source line comprises a conductive magnetic material providing a magnetic bias field extending to the magnetic tunnel junction of the selected memory cell for assisting the switching of the cell state when the write current is flowing.

A spin-orbit torque device 100 is described. In an embodiment, the spin-orbit torque device 100 comprises: a first pinning region 106 having a first fixed magnetization direction; a second pinning region 108 having a second fixed magnetization direction which is in a different direction to the first fixed magnetization direction; a magnetic layer 102 having a switchable magnetization direction; and a spin source layer 104 configured to generate a spin current for propagating a domain wall between the first and second pinning regions 106, 108 to switch the switchable magnetization direction of the magnetic layer 102 between the first and second fixed magnetization directions.