There is provided a magnetic element including a ferromagnetic reference layer having a fixed or pinned magnetization direction, a ferromagnetic free layer having a switchable magnetization direction based on spin transfer torque, an insulating spacer layer disposed between the ferromagnetic reference layer and the ferromagnetic free layer such that the ferromagnetic reference layer, the insulating spacer layer, and the ferromagnetic free layer form a magnetic tunnel junction, and at least one multilayer disposed on or in the magnetic tunnel junction, the at least one multilayer including Co/Ni/Pt which exhibits perpendicular magnetic anisotropy. There is also provided a corresponding method of fabricating such a magnetic element and a magnetic memory device including an array of such magnetic elements.

A storage element includes a layer structure including a storage layer having a direction of magnetization which changes according to information, a magnetization fixed layer having a fixed direction of magnetization, and an intermediate layer disposed therebetween, which intermediate layer contains a nonmagnetic material. The magnetization fixed layer has at least two ferromagnetic layers having a direction of magnetization tilted from a direction perpendicular to a film surface, which are laminated and magnetically coupled interposing a coupling layer therebetween. This configuration may effectively prevent divergence of magnetization reversal time due to directions of magnetization of the storage layer and the magnetization fixed layer being substantially parallel or antiparallel, reduce write errors, and enable writing operation in a short time.

A magnetization control element according to an aspect of the invention includes a magnetization control layer containing a magnetoelectric material exhibiting a magnetoelectric effect, and a magnetic coupling layer that is magnetically coupled to a magnetization of a first surface of the magnetization control layer through exchange coupling and exhibits a magnetic state according to the magnetization of the first surface, wherein a magnetization having a component in a direction opposite to a direction of a magnetization of the magnetic coupling layer is imparted to the magnetization control layer.

A magnetic field sensor based on two anti-ferromagnetically coupled magnetic layers separated by multilayer graphene, prepared in a single sputter chamber without a vacuum break.

A multilayer free magnetic layer structure for spin-based magnetic memory is provided herein. The multilayer free magnetic structure is employed in a magnetic tunnel junction (MTJ) and includes antiferromagnetically coupled magnetic layers. In some cases, the antiferromagnetic coupling is mediated by RKKY interaction with a Ru, Ir, Mo, Cu, or Rh spacer layer. In some cases, low damping magnetic materials, such as CoFeB, FeB, or CoFeBMo are used for the antiferromagnetically coupled magnetic layers. By employing the multilayer free magnetic structure for the MTJ as variously described herein, the critical or switching current can be significantly reduced compared to, for example, an MTJ employing a single-layer free magnetic layer. Thus, higher device efficiencies can be achieved. In some cases, the magnetic layers of the multilayer free magnetic structure are perpendicular magnets, which can be employed, for example, in perpendicular spin-orbit torque (pSOT) memory devices.

A magnetic tunneling junction (MTJ) memory device including a free and fixed (reference) magnet between first and second electrodes, and a synthetic antiferromagnet structure (SAF) structure between the fixed magnet and one of the electrodes. The SAF structure includes a magnetic skyrmion. Two magnetic skyrmions within a SAF structure may have opposing polarity. A SAF structure may further include a coupling layer between two magnetic layers, as well as interface layers separated from the coupling layer by one of the magnetic layers. The coupling layer may have a spin-orbit coupling effect on the magnetic layers that is of a sign opposite that of the interface layers, for example to promote formation of the magnetic skyrmions.

A tunneling magnetoresistance (TMR) sensor device is disclosed that includes one or more TMR resistors. The TMR sensor device comprises a first TMR resistor comprising a first TMR film, a second TMR resistor comprising a second TMR film different than the first TMR film, a third TMR resistor comprising the second TMR film, and a fourth TMR resistor comprising the first TMR film. The first and fourth TMR resistors are disposed in a first plane while the second and third TMR resistors are disposed in a second plane different than the first plane. The first TMR film comprises a synthetic anti-ferromagnetic pinned layer having a magnetization direction of a reference layer orthogonal to a magnetization direction a free layer. The second TMR film comprises a double synthetic anti-ferromagnetic pinned layer having a magnetization direction of a reference layer orthogonal to a magnetization direction of a free layer.

To provide a key monocrystalline magnetoresistance element necessary for accomplishing mass production and cost reduction for applying a monocrystalline giant magnetoresistance element using a Heusler alloy to practical devices. A monocrystalline magnetoresistance element of the present invention includes a silicon substrate 11, a base layer 12 having a B2 structure laminated on the silicon substrate 11, a first non-magnetic layer 13 laminated on the base layer 12 having a B2 structure, and a giant magnetoresistance effect layer 17 having at least one laminate layer including a lower ferromagnetic layer 14, an upper ferromagnetic layer 16, and a second non-magnetic layer 15 disposed between the lower ferromagnetic layer 14 and the upper ferromagnetic layer 16.

A storage element includes a storage layer, a fixed magnetization layer, a spin barrier layer, and a spin absorption layer. The storage layer stores information based on a magnetization state of a magnetic material. The fixed magnetization layer is provided for the storage layer through a tunnel insulating layer. The spin barrier layer suppresses diffusion of spin-polarized electrons and is provided on the side of the storage layer opposite the fixed magnetization layer. The spin absorption layer is formed of a nonmagnetic metal layer causing spin pumping and provided on the side of the spin barrier layer opposite the storage layer. A direction of magnetization in the storage layer is changed by passing current in a layering direction to inject spin-polarized electrons so that information is recorded in the storage layer and the spin barrier layer includes at least a material selected from oxides, nitrides, and fluorides.

A storage element includes a storage layer, a fixed magnetization layer, a spin barrier layer, and a spin absorption layer. The storage layer stores information based on a magnetization state of a magnetic material. The fixed magnetization layer is provided for the storage layer through a tunnel insulating layer. The spin barrier layer suppresses diffusion of spin-polarized electrons and is provided on the side of the storage layer opposite the fixed magnetization layer. The spin absorption layer is formed of a nonmagnetic metal layer causing spin pumping and provided on the side of the spin barrier layer opposite the storage layer. A direction of magnetization in the storage layer is changed by passing current in a layering direction to inject spin-polarized electrons so that information is recorded in the storage layer and the spin barrier layer includes at least a material selected from oxides, nitrides, and fluorides.