A memory apparatus includes a first electrode having a spin orbit material. The memory apparatus further includes a first memory device on a portion of the first electrode and a first dielectric adjacent to a sidewall of the first memory device. The memory apparatus further includes a second memory device on a portion of the first electrode and a second dielectric adjacent to a sidewall of the second memory device. A second electrode is on and in contact with a portion of the first electrode, where the second electrode is between the first memory device and the second memory device. The second electrode has a lower electrical resistance than an electrical resistance of the first electrode. The memory apparatus further includes a first interconnect structure and a second interconnect, each coupled with the first electrode.

A memory apparatus includes a first electrode having a spin orbit material. The memory apparatus further includes a first memory device on a portion of the first electrode and a first dielectric adjacent to a sidewall of the first memory device. The memory apparatus further includes a second memory device on a portion of the first electrode and a second dielectric adjacent to a sidewall of the second memory device. A second electrode is on and in contact with a portion of the first electrode, where the second electrode is between the first memory device and the second memory device. The second electrode has a lower electrical resistance than an electrical resistance of the first electrode. The memory apparatus further includes a first interconnect structure and a second interconnect, each coupled with the first electrode.

A perpendicular magnetic tunnel junction is disclosed wherein a metal insertion (MIS) layer is formed within a free layer (FL), a partially oxidized Hk enhancing layer is on the FL, and a nitride capping layer having a buffer layer/nitride layer (NL) is on the Hk enhancing layer to provide an improved coercivity (Hc)/switching current (Jc) ratio for spintronic applications. Magnetoresistive ratio is maintained above 100%, resistance×area (RA) product is below 5 ohm/μm.sup.2, and thermal stability to 400° C. is realized. The FL comprises two or more sub-layers, and the MIS layer may be formed within at least one sub-layer or between sub-layers. The buffer layer is used to prevent oxygen diffusion to the NL, and nitrogen diffusion from the NL to the FL. FL thickness is from 11 Angstroms to 25 Angstroms while MIS layer thickness is preferably from 0.5 Angstroms to 4 Angstroms.

A perpendicular magnetic tunnel junction is disclosed wherein a metal insertion (MIS) layer is formed within a free layer (FL), a partially oxidized Hk enhancing layer is on the FL, and a nitride capping layer having a buffer layer/nitride layer (NL) is on the Hk enhancing layer to provide an improved coercivity (Hc)/switching current (Jc) ratio for spintronic applications. Magnetoresistive ratio is maintained above 100%, resistance×area (RA) product is below 5 ohm/μm.sup.2, and thermal stability to 400° C. is realized. The FL comprises two or more sub-layers, and the MIS layer may be formed within at least one sub-layer or between sub-layers. The buffer layer is used to prevent oxygen diffusion to the NL, and nitrogen diffusion from the NL to the FL. FL thickness is from 11 Angstroms to 25 Angstroms while MIS layer thickness is preferably from 0.5 Angstroms to 4 Angstroms.

A one-dimensional magnetic field sensor comprises a support, a single elongated magnetic field concentrator or two magnetic field concentrators, which are separated by a first gap, and at least one magnetic sensor element. The magnetic field concentrator, or both thereof, consists of at least two parts which are separated from each other by second gaps. A two-dimensional magnetic field sensor comprises a support, a single magnetic field concentrator which consists of at least three parts which are separated from each other by gaps, and at least two magnetic sensor elements.

A magnetic memory device includes a cylindrical core; a plurality of layers surrounding the cylindrical core; a first terminal connected to a first end of the cylindrical core; and a second terminal connected to a second end of the cylindrical core, opposite the first end, wherein the first terminal is configured to receive a first current flowing radially from the cylindrical core through the plurality of layers, the first current imparting a torque on, at least, a magnetization of an inner layer of the plurality of layers.

A probabilistic bit (p-bit) comprises a magnetic tunnel junction (MTJ) comprising a free layer whose magnetization orientation randomly fluctuates in the presence of thermal noise. The p-bit MTJ comprises a reference layer, a free layer, and an insulating layer between the reference and free layers. The reference layer and the free layer comprise synthetic antiferromagnets. The use of a synthetic antiferromagnet for the reference layer reduces the amount of stray magnetic field that can impact the magnetization of the free layer and the use of a synthetic antiferromagnet for the free layer reduces stray magnetic field bias on p-bit random number generation. Tuning the thickness of the nonmagnetic layer of synthetic antiferromagnet free layer can result in faster random number generation time relative to a comparable MTJ with a free layer comprising a single-layer ferromagnet.

A probabilistic bit (p-bit) comprises a magnetic tunnel junction (MTJ) comprising a free layer whose magnetization orientation randomly fluctuates in the presence of thermal noise. The p-bit MTJ comprises a reference layer, a free layer, and an insulating layer between the reference and free layers. The reference layer and the free layer comprise synthetic antiferromagnets. The use of a synthetic antiferromagnet for the reference layer reduces the amount of stray magnetic field that can impact the magnetization of the free layer and the use of a synthetic antiferromagnet for the free layer reduces stray magnetic field bias on p-bit random number generation. Tuning the thickness of the nonmagnetic layer of synthetic antiferromagnet free layer can result in faster random number generation time relative to a comparable MTJ with a free layer comprising a single-layer ferromagnet.

A magnetic memory device includes first, second, and third conductor layers, and a memory cell that is coupled to the first, second, and third conductor layers. The memory cell includes a fourth conductor layer and a magnetoresistance effect element. The fourth conductor layer includes first, second, and third portions coupled to the first, second, and third conductor layers, respectively. The third portion is between the first and second portions. The magnetoresistance effect element is coupled between a third conductor and the fourth conductor layer. The fourth conductor layer includes a magnetic layer and a non-magnetic layer that is between the magnetic layer and the magnetoresistance effect element. The magnetic layer has a first saturation magnetization during a standby state or a read state of the memory cell, and has a second saturation magnetization larger than the first saturation magnetization during a write state of the memory cell.

A magnetic memory device includes first, second, and third conductor layers, and a memory cell that is coupled to the first, second, and third conductor layers. The memory cell includes a fourth conductor layer and a magnetoresistance effect element. The fourth conductor layer includes first, second, and third portions coupled to the first, second, and third conductor layers, respectively. The third portion is between the first and second portions. The magnetoresistance effect element is coupled between a third conductor and the fourth conductor layer. The fourth conductor layer includes a magnetic layer and a non-magnetic layer that is between the magnetic layer and the magnetoresistance effect element. The magnetic layer has a first saturation magnetization during a standby state or a read state of the memory cell, and has a second saturation magnetization larger than the first saturation magnetization during a write state of the memory cell.