A topological spin memory effect, defined as the recovery of magnetic skyrmions or magnetic bubble skyrmions in magnetic thin films after a transition to a dramatically different spin texture, is used for encrypted non-volatile information storage. The storage strategy is based on magnetic skyrmions, that is, topologically protected spin textures comprising chiral domain walls surrounding small (e.g., nanometers to microns in diameter), typically circular, single-domain cores. Systems and methods are described for encrypted non-volatile information storage based on a spin memory effect in magnetic thin films that support skyrmions. Systems and methods encrypt and recover information stored in the form of magnetic skyrmions.

The magnetic sensor can prevent an increase of a positional detection error of a subject/object even in the case of applying an external magnetic field with a magnetic field intensity exceeding a predetermined range. A magnetic sensor is equipped with a magnetoresistive effect element (MR element) 11 that can detect an external magnetic field and a soft magnetic body shield 12. The soft magnetic body shield(s) 12 are/is positioned above and/or below the MR element 11 in a side view, and the size of the MR element 11 is physically included within a perimeter of the soft magnetic body shield 12.

An exchange-coupled film includes a antiferromagnetic layer and a pinned magnetic layer including a ferromagnetic layer stacked together, the antiferromagnetic layer having a structure including an IrMn layer, a first PtMn layer, a PtCr layer, and a second PtMn layer stacked in that order, the IrMn layer being in contact with the pinned magnetic layer. The second PtMn layer preferably has a thickness of more than 0 Å and less than 60 Å, in some cases. The PtCr layer preferably has a thickness of 100 Å or more, in some cases. The antiferromagnetic layer preferably has a total thickness of 200 Å or less, in some cases.

A magnetic sensor device having a spin-valve-type magnetoresistive effect element and capable of stably applying a bias magnetic field on the free layer of the magnetoresistive effect element includes a spin-valve-type magnetoresistive effect element, a substrate on which the magnetoresistive effect element is positioned, a power source that supplies a substantially constant electric current applied on the magnetoresistive effect element, and a magnetic field generator that is connected to the electric current path of the electric current applied on the magnetoresistive effect element in series. The magnetic field generator is provided to be capable of applying a bias magnetic field on at least a portion of the magnetoresistive effect element. The magnetic field generator is close to a portion of the magnetoresistive effect element and is positioned at a different level from the substrate.

A magnetoresistive sensor includes a first non-magnetic layer, a second non-magnetic layer, and a magnetic free bi-layer. The magnetic free bi-layer is disposed between first non-magnetic layer and the second non-magnetic layer, the magnetic free bi-layer including a first magnetic free layer coupled to a second magnetic free layer. The first magnetic free layer is coupled to the first non-magnetic layer, and the second magnetic free layer is coupled to the second non-magnetic layer. The second non-magnetic layer comprises a non-magnetic material having an atomic radius within 10% of an atomic radius of at least one of the first magnetic free layer and the second magnetic free layer.

A magnetoresistive element comprises a novel iPMA cap layer on a surface of a recording layer to induce a giant interfacial perpendicular magnetic anisotropy (G-iPMA) of the recording layer and a method of making the same. The recording layer comprises a first free layer immediately contacting to the tunnel barrier layer and having a body-centered cubic structure with a (100) texture, and a second free layer having a body-centered cubic structure with a (110) texture or a face-centered cubic structure with a (111) texture, and a crystal-breaking layer inserted between the first free layer and the second free layer.

A magnetic sensor device includes a first magnetic sensor, a second magnetic sensor, and a soft magnetic structure. The first magnetic sensor generates a detection value corresponding to a component in a direction parallel to an X direction of an external magnetic field. The second magnetic sensor generates a detection value corresponding to a component in a direction parallel to a Y direction of the external magnetic field. In the presence of a residual magnetization in the X direction in the soft magnetic structure, a magnetic field that is based on the residual magnetization and contains a component in the −X direction is applied to the first magnetic sensor. In the presence of a residual magnetization in the Y direction in the soft magnetic structure, a magnetic field that is based on the residual magnetization and contains a component in the −Y direction is applied to the second magnetic sensor.

An electronic device may include a semiconductor memory, and the semiconductor memory may include a substrate; a variable resistance element formed over the substrate and exhibiting different resistance values representing different digital information, the variable resistance element including a free layer having a variable magnetization direction, a pinned layer having a fixed magnetization direction and a tunnel barrier layer interposed between the free layer and the pinned layer; and a blocking layer disposed on at least sidewalls of the variable resistance element, wherein the blocking layer may include a layer that is substantially free of nitrogen, oxygen or a combination thereof.

An apparatus is provided which comprises: a magnetic junction including: a stack of structures including: a first structure comprising a magnet with an unfixed perpendicular magnetic anisotropy (PMA) relative to an x-y plane of a device, wherein the first structure has a first dimension along the x-y plane and a second dimension in the z-plane, wherein the second dimension is substantially greater than the first dimension. The magnetic junction includes a second structure comprising one of a dielectric or metal; and a third structure comprising a magnet with fixed PMA, wherein the third structure has an anisotropy axis perpendicular to the plane of the device, and wherein the third structure is adjacent to the second structure such that the second structure is between the first and third structures; and an interconnect adjacent to the third structure, wherein the interconnect comprises a spin orbit material.

The magnetic sensor can prevent an increase of a positional detection error of a subject/object even in the case of applying an external magnetic field with a magnetic field intensity exceeding a predetermined range. A magnetic sensor is equipped with a magnetoresistive effect element (MR element) 11 that can detect an external magnetic field and a soft magnetic body shield 12. The soft magnetic body shield(s) 12 are/is positioned above and/or below the MR element 11 in a side view, and the size of the MR element 11 is physically included within a perimeter of the soft magnetic body shield 12.