The present disclosure relates to magnetic devices. In particular, the disclosure relates to magnetic memory and logic devices that employ the voltage control of magnetic anisotropy (VCMA) effect for magnetization switching. The present disclosure provides a method for manufacturing a magnetic structure for such a magnetic device. The method comprising the following steps: providing a bottom electrode layer, forming a SrTiO.sub.3 (STO) stack on the bottom electrode layer by atomic layer deposition (ALD) of at least two different STO nanolaminates, forming a magnetic layer on the STO stack, and forming a perpendicular magnetic anisotropy (PMA) promoting layer on the magnetic layer, the PMA promoting layer being configured to promote PMA in the magnetic layer.

A perpendicularly magnetized magnetic tunnel junction (p-MTJ) is disclosed wherein a boron containing free layer (FL) is subjected to a plasma treatment with inert gas, and a natural oxidation (NOX) process to form B.sub.2O.sub.3 before overlying layers are deposited. A metal layer such as Mg is deposited on the FL as a first step in forming a Hk enhancing layer that increases FL perpendicular magnetic anisotropy, or as a first step in forming a tunnel barrier layer on the FL. One or more anneal steps are essential in assisting B.sub.2O.sub.3 segregation from the free layer and thereby increasing the FL magnetic moment. A post-oxidation plasma treatment may also be used to partially remove B.sub.2O.sub.3 proximate to the FL top surface before the metal layer is deposited. Both plasma treatments use low power (<50 Watts) to remove a maximum of 2 Angstroms FL thickness.

Magnetoelectric or magnetoresistive memory cells include at least one of a high dielectric constant dielectric capping layer and/or a nonmagnetic metal dust layer located between the free layer and the dielectric capping layer.

A magnetic sensor includes: a substrate; and first and second magnetoresistive devices on one surface of the substrate. Each of the first and second magnetoresistive devices includes: a fixed layer having an easy magnetization axis perpendicular to the one surface and having a fixed magnetization direction; a free layer having a variable magnetization direction; and an intermediate layer made of a non-magnetic material and arranged between the fixed layer and the free layer. The fixed layer includes a first ferromagnetic layer, a second ferromagnetic layer, and a non-magnetic layer arranged between the first ferromagnetic layer and the second ferromagnetic layer.

A dual magnetic tunnel junction (DMTJ) is disclosed with a PL1/TB1/free layer/TB2/PL2/capping layer configuration wherein a first tunnel barrier (TB1) has a substantially lower resistance x area (RA.sub.1) product than RA.sub.2 for an overlying second tunnel barrier (TB2) to provide an acceptable net magnetoresistive ratio (DRR). Moreover, magnetizations in first and second pinned layers, PL1 and PL2, respectively, are aligned antiparallel to enable a lower critical switching current than when in a parallel alignment. An oxide capping layer having a RA.sub.CAP is formed on PL2 to provide higher PL2 stability. The condition RA.sub.1<RA.sub.2 and RA.sub.CAP<RA.sub.2 is achieved when TB1 and the oxide capping layer have one or both of a smaller thickness and a lower oxidation state than TB2, are comprised of conductive (metal) channels in a metal oxide or metal oxynitride matrix, or are comprised of a doped metal oxide or doped metal oxynitride layer.

A magnetic memory device includes a buffer layer on a substrate, a magnetic tunnel junction structure including a fixed layer structure, a tunnel barrier, and a free layer that are sequentially arranged on the buffer layer, and a spin-orbit torque (SOT) structure on the magnetic tunnel junction structure and including a topological insulator material, wherein the free layer includes a Heusler material.

A method of fabricating an MRAM device includes forming a bottom electrode over a semiconductor substrate, forming a magnetic tunnel junction (MTJ) structure on the bottom electrode, and forming a top electrode on the MTJ structure. The method also includes forming spacers on sidewalls of the top electrode and the MTJ structure, and depositing a first dielectric layer to surround the spacers. The method further includes selectively depositing a patterned etch stop layer on the first dielectric layer and the spacers. In addition, the method includes depositing a second dielectric layer on the patterned etch stop layer and the top electrode, forming a via hole in the second dielectric layer to expose the top electrode, and forming a top electrode via in the via hole.

A method for etching a magnetic tunneling junction (MTJ) structure is described. A stack of MTJ layers on a bottom electrode on a wafer is provided. A metal hard mask layer is provided on the MTJ stack. A stack of multiple dielectric hard masks is formed on the metal hard mask wherein each successive dielectric hard mask has etch selectivity with respect to its underlying and overlying layers. The dielectric hard mask layers are etched in turn selectively with respect to their underlying and overlying layers wherein each successive pattern size is smaller than the preceding pattern size. The MTJ stack is etched selectively with respect to the bottommost combination dielectric and metal hard mask pattern to form a MTJ device having a MTJ pattern size smaller than a bottommost pattern size.

A device and to a method of producing a device, wherein the method includes, inter alia, providing a substrate and generating at least two mutually spaced-apart cavities within the substrate. In accordance with the invention, each cavity has a depth of at least 50 m. The cavities are filled up with magnetic particles, wherein the magnetic particles enter into contact with one another at points of contact, and wherein cavities are formed between the points of contact. At least some of the magnetic particles are connected to one another at their points of contact, specifically by coating the magnetic particles, wherein the cavities are at least partly penetrated by the layer produced in the coating process, so that the connected magnetic particles form a magnetic porous structure.

The present invention relates to the technical field of superlattice magneto-optical material technologies, and in particular, to a superlattice material, and a preparation method and application thereof. According to description of embodiments, the superlattice material provided in the present invention has both a relatively good magnetic property of a ferrous garnet material and a good photoelectric absorption characteristic of a two-dimensional semiconductor material such as graphene. Magneto-optical Kerr effect data obtained through testing shows that: A saturated magneto-optical Kerr angle of the superlattice material in the present invention is 13 mdeg in a magnetic field of 2500 Oe, and a magneto-optical Kerr angle of the superlattice material is increased by 2.5 times compared with a nonsuperlattice ferrimagnetic thin film material into which no two-dimensional material is inserted, thereby achieving magneto-optical effect enhancement.