The present disclosure generally relate to spin-orbit torque (SOT) magnetic tunnel junction (MTJ) devices comprising a buffer layer, a bismuth antimony (BiSb) layer having a (012) orientation disposed on the buffer layer, and an interlayer disposed on the BiSb layer. The buffer layer and the interlayer may each independently be a single layer of material or a multilayer of material. The buffer layer and the interlayer each comprise at least one of a covalently bonded amorphous material, a tetragonal (001) material, a tetragonal (110) material, a body-centered cubic (bcc) (100) material, a face-centered cubic (fcc) (100) material, a textured bcc (100) material, a textured fcc (100) material, a textured (100) material, or an amorphous metallic material. The buffer layer and the interlayer inhibit antimony (Sb) migration within the BiSb layer and enhance uniformity of the BiSb layer while further promoting the (012) orientation of the BiSb layer.

A spin-orbit torque magnetoresistive random-access memory device formed by fabricating a spin-Hall-effect (SHE) layer above and in electrical contact with a transistor, forming a spin-orbit-torque (SOT) magnetoresistive random access memory (MRAM) cell stack disposed above and in electrical contact with the SHE rail, wherein the SOT-MRAM cell stack comprises a free layer, a tunnel junction layer, a reference layer, and a diode structure, forming a write line disposed in electrical contact with the SHE rail, forming a protective dielectric layer covering a portion of the SOT-MRAM cell stack, and forming a read line disposed above and adjacent to the diode structure.

A magnetic memory device includes a conductive line extending in a first direction, a magnetic tunnel junction structure on a first surface of the conductive line, the magnetic tunnel junction structure comprising at least two magnetic patterns and a barrier pattern between the at least two magnetic patterns, and a magnetic layer on a second surface of the conductive line, which is opposite to the first surface. The magnetic layer includes magnetization components having a magnetization in a direction which is parallel to the second surface and intersects the first direction.

There is provided a magnetoresistance effect element includes: a channel layer that extends in a first direction; a recording layer which includes a film formed from a ferromagnetic material, of which a magnetization state is changed to one of two or greater magnetization states, and which is formed on the channel layer; a non-magnetic layer that is provided on a surface of the recording layer; a reference layer which is provided on a surface of the non-magnetic layer, which includes a film formed from a ferromagnetic material, and of which a magnetization direction is fixed; a terminal pair that includes a first terminal and a second terminal which are electrically connected to the channel layer with an interval in the first direction, and to which a current pulse for bringing the recording layer to any one magnetization state with a plurality of pulses is input by flowing a current to the channel layer between the first terminal and the second terminal; and a third terminal that is electrically connected to the reference layer.

A spin orbit memory device includes a material layer stack on a spin orbit electrode. The material layer stack includes a magnetic tunnel junction (MTJ) and a synthetic antiferromagnetic (SAF) structure on the MTJ. The SAF structure includes a first magnet structure and a second magnet structure separated by an antiferromagnetic coupling layer. The first magnet structure includes a first magnet and a second magnet separated by a single layer of a non-magnetic material such as platinum. The second magnet structure includes a stack of bilayers, where each bilayer includes a layer of platinum on a layer of a magnetic material such.

A sensor device comprising: a lead frame; a first/second semiconductor die having a first/second sensor structure at a first/second sensor location, and a plurality of first/second bond pads electrically connected to the lead frame; the semiconductor dies having a square or rectangular shape with a geometric center; the sensor locations are offset from the geometrical centers; the second die is stacked on top of the first die, and is rotated by a non-zero angle and optionally also offset or shifted with respect to the first die, such that a perpendicular projection of the first and second sensor location coincide.

An electronic device may include a first electrode, a first magnetostrictive layer electrically coupled to the first electrode, a first ferroelectric layer above the first ferromagnetic layer, and a ferromagnetic layer above the first ferroelectric layer. The electronic device may further include a second electrode electrically coupled to the ferromagnetic layer, a second ferroelectric layer above the ferromagnetic layer, a second magnetostrictive layer above the second ferroelectric layer, and a third electrode electrically coupled to the second magnetostrictive layer. The first ferroelectric layer may be switchable between different polarization states responsive to a first voltage applied across the first and second electrodes, and the second ferroelectric layer may be switchable between different polarization states responsive to a second voltage applied across the second and third electrodes.

An electronic device may include a first electrode, a first magnetostrictive layer electrically coupled to the first electrode, a first ferroelectric layer above the first ferromagnetic layer, and a ferromagnetic layer above the first ferroelectric layer. The electronic device may further include a second electrode electrically coupled to the ferromagnetic layer, a second ferroelectric layer above the ferromagnetic layer, a second magnetostrictive layer above the second ferroelectric layer, and a third electrode electrically coupled to the second magnetostrictive layer. The first ferroelectric layer may be switchable between different polarization states responsive to a first voltage applied across the first and second electrodes, and the second ferroelectric layer may be switchable between different polarization states responsive to a second voltage applied across the second and third electrodes.

Provided are a function switchable random access memory, including: two electromagnetic portions configured to connect a current; a magnetic recording portion between the two electromagnetic portions and including a spin-orbit coupling layer and a magnetic tunnel junction; a pinning region between each of the electromagnetic portions and the magnetic recording portion; a cut-off region on a side of each of the electromagnetic portions opposite to the pinning region, the spin-orbit coupling layer is configured to generate a spin current under an action of the current; the two electromagnetic portions is configured to generate two magnetic domains with magnetization pointing in opposite directions under an action of the spin current; the magnetic tunnel junction is configured to generate a magnetic domain wall based on the two opposite magnetic domains and is configured to drive the magnetic domain wall to reciprocate under the action of the spin current.

Disclosed are an artificial antiferromagnetic structure and a storage element. The artificial antiferromagnetic structure includes a first metal layer, an artificially synthesized antiferromagnetic layer and a second metal layer that are stacked in sequence, wherein there is an interfacial DM (Dzyaloshinskii-Moriya) interaction at an interface between the metal layer and the artificially synthesized antiferromagnetic layer, such that there is a first interfacial DM interaction between the first metal layer and the artificially synthesized antiferromagnetic layer, there is a second interfacial DM interaction between the second metal layer and the artificially synthesized antiferromagnetic layer, and the first interfacial DM interaction is different from the second interfacial DM interaction. The artificially synthesized antiferromagnetic layer forms a stable chiral Néel magnetic domain wall due to a strong interfacial DM interaction.