A packaged current sensor includes a lead frame, an integrated circuit, an isolation spacer, a first magnetic concentrator, and a second magnetic concentrator. The lead frame includes a conductor. The isolation spacer is between the lead frame and the integrated circuit. The first magnetic concentrator is aligned with the conductor. The second magnetic concentrator is aligned with the conductor.

This spin current magnetization rotational type magnetoresistive element includes a magnetoresistive effect element having a first ferromagnetic metal layer having a fixed magnetization orientation, a second ferromagnetic metal layer having a variable magnetization orientation, and a non-magnetic layer sandwiched between the first ferromagnetic metal layer and the second ferromagnetic metal layer, and spin-orbit torque wiring which extends in a direction that intersects the stacking direction of the magnetoresistive effect element, and is connected to the second ferromagnetic metal layer, wherein the electric current that flows through the magnetoresistive effect element and the electric current that flows through the spin-orbit torque wiring merge or are distributed in the portion where the magnetoresistive effect element and the spin-orbit torque wiring are connected.

A spin current magnetization rotational element according to the present disclosure includes a first ferromagnetic metal layer configured for a direction of magnetization to be changed and a spin-orbit torque wiring extending in a direction intersecting a lamination direction of the first ferromagnetic metal layer and bonded to the first ferromagnetic metal layer. The spin-orbit torque wiring includes a narrow portion, and at least a part of the narrow portion constitutes a junction to the first ferromagnetic metal layer.

A spin current magnetization rotational element according to the present disclosure includes a first ferromagnetic metal layer configured for a direction of magnetization to be changed and a spin-orbit torque wiring extending in a direction intersecting a lamination direction of the first ferromagnetic metal layer and bonded to the first ferromagnetic metal layer. The spin-orbit torque wiring includes a narrow portion, and at least a part of the narrow portion constitutes a junction to the first ferromagnetic metal layer.

An integrated Hall sensor is provided with: a main wafer (10) of semiconductor material having a substrate (101) with a first surface (101a) and a second surface (101b), opposite to the first surface (101a) along a vertical axis (y); Hall sensor terminals (1, 2, 3, 4; 1′, 2′, 3′, 4′) arranged at least one of the first and second surfaces (101a, 101b) of the substrate (101); an isolation structure (109) in the substrate (101) defining a Hall sensor plate (103) of the integrated Hall sensor, the Hall sensor terminals being arranged in the isolation structure (109). The integrated Hall sensor moreover has a test or calibration coil integrated in the wafer (10), having a plurality of windings formed, at least in part, by metal portions (130b, 170b; 130a, 170a) arranged above the first and second surfaces (101a, 101b) of the substrate (101) and defining an inner volume (1001) entirely enclosing the Hall sensor plate (103).

A switching device is disclosed. The switching device includes a spin-orbit coupling (SOC) layer, a pure spin conductor (PSC) layer disposed atop the SOC layer, a ferromagnetic (FM) layer disposed atop the PSC layer, and a normal metal (NM) layer sandwiched between the PSC layer and the FM layer. The PSC layer is a ferromagnetic insulator (FMI) is configured to funnel spins from the SOC layer onto the NM layer and to further provide a charge insulation so as to substantially eliminate current shunting from the SOC layer while allowing spins to pass through. The NM layer is configured to funnel spins from the PSC layer into the FM layer.

Approaches for embedding spin hall MTJ devices into a logic processor, and the resulting structures, are described. In an example, a logic processor includes a logic region including fin-FET transistors disposed in a dielectric layer disposed above a substrate. The logic processor also includes a memory array including a plurality of two-transistor one magnetic tunnel junction (MTJ) spin hall electrode (2T1MTJ SHE) bit cells. The transistors of the 2T1MTJ SHE bit cells are fin-FET transistors disposed in the dielectric layer.

A non-volatile data retention circuit includes a complementary latch configured to generate and store complementary non-volatile spin states corresponding to an input signal when in a write mode, and to concurrently generate a first charge current signal and a second charge current corresponding to the complementary non-volatile spin states when in read mode, and a differential amplifier coupled to the complementary latch and configured to generate an output signal based on the first and second charge current signals.

A magnetic memory (MRAM) cell, comprising: a first layer formed from a substantially electrically conductive material; and a magnetic tunnel junction (MTJ) stack formed over the first layer, wherein the MTJ stack comprises: a ferromagnetic reference layer having an in-plane reference magnetization; a tunnel barrier layer; and a ferromagnetic storage layer between the tunnel barrier layer and the first layer, the storage layer having an in-plane storage magnetization; wherein the MTJ stack comprises an arrangement for providing an in-plane uniaxial anisotropy in the storage layer; wherein said in-plane uniaxial anisotropy makes an angle with the direction of the write current that is between 5° and 90°, and wherein said in-plane uniaxial anisotropy has an energy between 40 and 200 kBT and wherein coercivity is larger than 200 Oe.

A spin-orbit-torque magnetization rotational element includes: a spin-orbit-torque wiring; and a laminated body laminated on the spin-orbit-torque wiring, wherein the laminated body includes a first ferromagnetic layer, an oxide containing layer, and a second ferromagnetic layer in order from the spin-orbit-torque wiring, wherein the oxide containing layer contains an oxide of a non-magnetic element, and wherein the first ferromagnetic layer and the second ferromagnetic layer are ferromagnetically coupled to each other.