A memory device may comprise a substrate defining a main plane; a plurality of memory cells each comprising a SOT current layer disposed in the main plane of the substrate and a magnetic tunnel junction residing on the SOT current layer; and a bit line and a source line to flow a write current in a write path including the SOT current layer of a selected memory cell. The source line comprises a conductive magnetic material providing a magnetic bias field extending to the magnetic tunnel junction of the selected memory cell for assisting the switching of the cell state when the write current is flowing.

The present invention is directed to a perpendicular magnetic structure comprising a first seed layer including tantalum, a second seed layer deposited on top of the first seed layer and including iridium, a third seed layer deposited on top of the second seed layer, and a fourth seed layer deposited on top of the third seed layer and including chromium. The third seed layer includes one of NiFe, NiFeB, NiFeCr, CoFeB, CoFeTa, CoFeW, CoFeMo, CoFeTaB, CoFeWB, or CoFeMoB. The perpendicular magnetic structure further includes a magnetic fixed layer structure formed on top of the fourth seed layer and having an invariable magnetization direction substantially perpendicular to a layer plane of the magnetic fixed layer structure. The magnetic fixed layer structure includes layers of a magnetic material interleaved with layers of a transition metal. The magnetic material includes cobalt. The transition metal includes one of nickel, platinum, palladium, or iridium.

A spin orbit torque (SOT) memory device includes an SOT electrode on an upper end of an MTJ device. The MTJ device includes a free magnet, a fixed magnet and a tunnel barrier between the free magnet and the fixed magnet and is coupled with a conductive interconnect at a lower end of the MTJ device. The SOT electrode has a footprint that is substantially the same as a footprint of the MTJ device. The SOT device includes a first contact and a second contact on an upper surface of the SOT electrode. The first contact and the second contact are laterally spaced apart by a distance that is no greater than a length of the MTJ device.

A device includes a resistance switching layer, a capping layer, a top electrode, a first spacer, and a second spacer. The resistance switching layer is over a substrate. The capping layer is over the resistance switching layer. The top electrode is over the capping layer. The first spacer lines the resistance switching layer and the capping layer. The second spacer lines the first spacer. The capping layer is in contact with the top electrode, the first spacer, and the second spacer.

A method of manufacturing a double magnetic tunnel junction device is provided. The method includes forming a first free layer, forming a first tunnel barrier layer on the free layer, forming a reference layer on the first tunnel barrier layer, forming a second tunnel barrier layer on the reference layer, and forming a second free layer on the second tunnel barrier layer. An area of the second free layer is less than an area of the first free layer. Also, the first free layer, the first tunnel barrier layer and the reference layer are a first magnetic tunnel junction, and the reference layer, the second tunnel barrier layer and the second free layer are a second magnetic tunnel junction.

A magnetoresistive random access memory (MRAM) cell includes a bottom electrode, a magnetic tunnel junction structure, a bipolar tunnel junction selector; and a top electrode. The tunnel junction selector includes a MgO tunnel barrier layer and provides a bipolar function for putting the MTJ structure in parallel or anti-parallel mode.

An integrated circuit (IC) device includes a logic portion including logic circuits in multiple vertically stacked metal layers interconnected by one or more via layers, and a memory portion with a plurality of magnetoresistive devices. Each magnetoresistive device is provided in a single metal layer of the multiple vertically stacked metal layers of the IC device.

Data storage devices are provided. A data storage device includes a memory transistor on a substrate and a data storage structure electrically connected to the memory transistor. The data storage structure includes a magnetic tunnel junction pattern and a top electrode on the magnetic tunnel junction pattern. The top electrode includes a first top electrode and a second top electrode on the first top electrode, and the first and second top electrodes include the same metal nitride. The first top electrode includes first crystal grains of the metal nitride, and the second top electrode includes second crystal grains of the metal nitride. In a section of the top electrode, the number of the first crystal grains per a unit length is greater than the number of the second crystal grains per the unit length.

A semiconductor structure and a method for forming the same, and a memory and a method for forming the same are provided. The method for forming the semiconductor structure includes: providing a substrate, in which a sacrificial layer and an active layer on the sacrificial layer are formed on the substrate; patterning the active layer and the sacrificial layer to form grooves which divide the active layer and the sacrificial layer into a plurality of active areas; filling the grooves to form a first isolation layer surrounding the active areas; patterning the active layer in the active areas to form a plurality of separate active patterns; removing the sacrificial layer via openings between adjacent active patterns to form gaps between bottoms of the active patterns and the substrate; forming bit lines in the gaps; and forming semiconductor pillars on partial tops of the active patterns.

A memory device includes a plurality of circuit layers, a plurality of first conductive through via structures and a plurality of bitlines. The circuit layers are disposed one above another, and each circuit layer includes one or more memory cell arrays. The first conductive through via structures penetrates though the circuit layers. Each of the bitlines includes a plurality of bitline segments disposed on the circuit layers respectively. The bitline segments are electrically connected through one of the first conductive through via structures. Each bitline segment is coupled to a plurality of memory cells of a memory cell array of a circuit layer where the bitline segment is disposed.