Forming a semiconductor device includes forming a first conductive line on a substrate, forming a memory cell including a switching device and a data storage element on the first conductive line, and forming a second conductive line on the memory cell. Forming the switching device includes forming a first semiconductor layer, forming a first doped region by injecting a n-type impurity into the first semiconductor layer, forming a second semiconductor layer thicker than the first semiconductor layer, on the first semiconductor layer having the first doped region, forming a second doped region by injecting a p-type impurity into an upper region of the second semiconductor layer, and forming a P-N diode by performing a heat treatment process to diffuse the n-type impurity and the p-type impurity in the first doped region and the second doped region to form a P-N junction of the P-N diode in the second semiconductor layer.

Technology for reading reversible resistivity cells in a memory array when using a current-force read is disclosed. The memory cells are first read using a current-force referenced read. If the current-force referenced read is successful, then results of the current-force referenced read are returned. If the current-force referenced read is unsuccessful, then a current-force self-referenced read (SRR) is performed and results of the current-force SRR are returned. The current-force referenced read provides a very fast read of the memory cells and can be successful in most cases. The current-force SRR provides a more accurate read in the event that the current-force referenced read is not successful. Moreover, the current-force referenced read may use less power than the current-force SRR. In an aspect this mixed current-force read is used for MRAM cells, which are especially challenging to read.

The present invention is directed to a magnetic memory cell including a magnetic tunnel junction (MTJ) memory element and a two-terminal bidirectional selector coupled in series between two conductive lines. The MTJ memory element includes a magnetic free layer, a magnetic reference layer, and an insulating tunnel junction layer interposed therebetween. The two-terminal bidirectional selector includes bottom and top electrodes, first and third volatile switching layers interposed between the bottom and top electrodes, and a second volatile switching layer interposed between the first and third volatile switching layers. The bottom and top electrodes each independently include one of titanium nitride or iridium. The first and third volatile switching layers each include tantalum oxide and silver. The second volatile switching layer includes hafnium oxide and has a higher electrical resistance than the first and third volatile switching layers.

According to one embodiment, a memory device includes first and second wiring lines, memory cells between first and second wiring lines, first and second common wiring lines, a first selecting circuit between one ends of the first wiring lines and the first common wiring line, and a second selecting circuit between the other ends of the first wiring lines and the first common wiring line. A path between the first wiring line and the first common wiring line through the first selecting circuit and a path between the first wiring line and the first common wiring line through the second selecting circuit are defined as first and second paths, one of the first and second paths is set to an electrically conductive state.

A network computation device includes a stack of a plurality of arrays of magnetic tunnel junctions that are spaced apart along a stack direction, and at least one filament-forming dielectric material layer located between each vertically neighboring pair of arrays of magnetic tunnel junctions selected from the plurality of magnetic tunnel junctions.

Aspects of the present disclosure are directed to magnetic tunnel junction (MTJ) structures comprising multiple MTJ bits connected in series. For example, a magnetic tunnel junction (MTJ) stack according to the present disclosure may include at least a first MTJ bit and a second MTJ bit stacked above the first MTJ bit, and a resistance state of the MTJ stack may be read by passing a single read current through both the first MTJ bit and the second MTJ bit.

Thermal field controlled electrical conductivity change devices and applications therefore are provided. In some embodiments, a thermal switch, comprises: a metal-insulator-transition (MIT) material; first and second terminals electrically coupled to the MIT material; and a heater disposed near the MIT material.

Provided are a semiconductor device and a semiconductor apparatus. The semiconductor device may include a first electrode; a second electrode spaced apart from the first electrode; and a selection device layer including a chalcogen compound layer between the first electrode and the second electrode and a metal oxide doped in the chalcogen compound layer. In the semiconductor device, by doping the metal oxide, an off-current value (leakage current value) of the selection device layer may be reduced, and static switching characteristics may be implemented.

Provided are a memory device and a method of forming the same. The memory device includes a plurality of bit lines extending along a first direction; a plurality of word lines extending along a second direction different from the first direction; a plurality of memory pillars; and a selector. The plurality of word lines are disposed over the plurality of bit lines. The plurality of memory pillars are disposed between the plurality of bit lines and the plurality of word lines, and respectively positioned at a plurality of intersections of the plurality of bit lines and the plurality of word lines. The selector is disposed between the plurality of memory pillar and the plurality of word lines. The selector extends from a top surface of one memory pillar to cover a top surface of an adjacent memory pillar. A semiconductor device having the memory device is also provided.

A non-volatile memory cell includes a thin film resistor (TFR) in series and between a top state influencing electrode and a top wire. The TFR limits or generally reduces the electrical current at the top state influencing electrode from the top wire. As such, non-volatile memory cell endurance may be improved and adverse impacts to component(s) that neighbor the non-volatile memory cell may be limited. The TFR is additionally utilized as an etch stop when forming a top wire trench associated with the fabrication of the top wire. In some non-volatile memory cells where cell symmetry is desired, an additional TFR may be formed between a bottom wire and a bottom state influencing electrode.