There is disclosed a memory element including a memory layer that has a magnetization perpendicular to a film face; a magnetization-fixed layer that has a magnetization that is perpendicular to the film face; and an insulating layer that is provided between the memory layer and the magnetization-fixed layer, wherein an electron that is spin-polarized is injected in a lamination direction of a layered structure, and thereby the magnetization direction of the memory layer varies and a recording of information is performed, a magnitude of an effective diamagnetic field which the memory layer receives is smaller than a saturated magnetization amount of the memory layer, and in regard to the insulating layer and the other side layer with which the memory layer comes into contact at a side opposite to the insulating layer, at least an interface that comes into contact with the memory layer is formed of an oxide film.

A memory slot including a pad formed of a stack of regions made of thin layers, including a first region made of a nonmagnetic conducting material; a second region made of a magnetic material exhibiting a magnetization in a direction perpendicular to the principal plane of the pad; a third region made of a nonmagnetic conducting material of different characteristics to those of the first region; the pad resting on a conducting track adapted to cause the flow of a programming current of chosen sense, in which the pad has an asymmetric shape with respect to any plane perpendicular to the plane of the layers and parallel to the central axis of the track, and with respect to its barycenter.

The present invention relates to a sensor device which has high S/N and excellent temperature characteristics. A sensor device has a semiconductor substrate, a first metal wiring layer provided on the semiconductor substrate, a first insulating layer provided on the first metal wiring layer, a compound semiconductor sensor element provided on the first insulating layer, a second metal wiring layer provided on the compound semiconductor sensor element and the first insulating layer, and a second insulating layer provided on the second metal wiring layer. A third insulating layer is provided between the first metal wiring layer and the second metal wiring layer, and the compound semiconductor sensor element is provided in the third insulating layer.

According to one embodiment, a magnetic memory device includes a magnetic memory chip having a magnetoresistive element, a magnetic layer having first and second portions spacing out each other, the first portion covering a first main surface of the magnetic memory chip, the second portion covering a second main surface facing the first main surface of the magnetic memory chip, a circuit board on which the magnetic layer is mounted, and a bonding wire connecting between the magnetic memory chip and the circuit board in a first direction parallel to the first and second main surfaces.

An MTJ structure having vertical magnetic anisotropy is provided. The MTJ structure having vertical magnetic anisotropy can comprise: a substrate; an artificial antiferromagnetic layer located on the substrate; a buffer layer located on the artificial antiferromagnetic layer, and including W or an alloy containing W; a first ferromagnetic layer located on the buffer layer, and having vertical magnetic anisotropy; a tunneling barrier layer located on the first ferromagnetic layer; and a second ferromagnetic layer located on the tunneling barrier layer, and having vertical magnetic anisotropy. Accordingly, in the application of bonding the artificial antiferromagnetic layer with a CoFeB/MgO/CoFeB structure, the MTJ structure having improved thermal stability at high temperature can be provided by using the buffer layer therebetween.

A magnetic tunnel junction (MTJ) is disclosed wherein a free layer (FL) interfaces with a first metal oxide (Mox) layer and second metal oxide (tunnel barrier) to produce perpendicular magnetic anisotropy (PMA) in the FL. In some embodiments, conductive metal channels made of a noble metal are formed in the Mox that is MgO to reduce parasitic resistance. In a second embodiment, a discontinuous MgO layer with a plurality of islands is formed as the Mox layer and a non-magnetic hard mask layer is deposited to fill spaces between adjacent islands and form shorting pathways through the Mox. In another embodiment, end portions between the sides of a center Mox portion and the MTJ sidewall are reduced to form shorting pathways by depositing a reducing metal layer on Mox sidewalls, or performing a reduction process with forming gas, H.sub.2, or a reducing species.

A memory structured in lines and columns over several superimposed levels, each level comprising an array of memory elements and gate-all-around access transistors, each transistor including a semiconductor nanowire and each gate being insulated from the gates of the other levels, further comprising: conductive portions, each crossing at least two levels and coupled to first ends of the nanowires of one column of the levels; memory stacks, each crossing the levels and coupled to second ends of the nanowires of said column; first conductive lines, each connected to the conductive portions of the same column; word lines each extending in the same level while coupling together the gates of the same line and located in said level.

A method of manufacturing and resultant device are directed to an inverted wide-base double magnetic tunnel junction device having both high-efficiency and high-retention arrays. The method includes a method of manufacturing, on a common stack, a high-efficiency array and a high-retention array for an inverted wide-base double magnetic tunnel junction device. The method comprises, for the high-efficiency array and the high-retention array, forming a first magnetic tunnel junction stack (MTJ2), forming a spin conducting layer on the MTJ2, and forming a second magnetic tunnel junction stack (MTJ1) on the spin conducting layer. The first magnetic tunnel junction stack for the high-retention array has a high-retention critical dimension (CD) (HRCD) that is larger than a high-efficiency CD (HECD) of the first magnetic tunnel junction stack for the high-efficiency array. The second magnetic tunnel junction stack (MTJ1) is shorted for the high-retention array and is not shorted for the high-efficiency array.

A storage layer of a magnetic tunnel junction (MTJ) element is disclosed. The storage layer having perpendicular magnetic anisotropy includes a first ferromagnetic layer, a first dust layer disposed directly on the first ferromagnetic layer, a second ferromagnetic layer disposed directly on the first dust layer, a second dust layer disposed directly on the second ferromagnetic layer, and a third ferromagnetic layer disposed directly on the second dust layer. A material of the first dust layer is different from a material of the second dust layer.

At least a portion of a memory cell is formed over a first substrate and at least a portion of a steering element or word or bit line of the memory cell is formed over a second substrate. The at least a portion of the memory cell is bonded to at least a portion of a steering element or word or bit line. At least one of the first or second substrate may be removed after the bonding.