A method of forming an electrical device that includes forming an amorphous semiconductor material on a metal surface of a memory device, in which the memory device is vertically stacked atop a first transistor. The amorphous semiconductor material is annealed with a laser anneal having a nanosecond duration to convert the amorphous semiconductor material into a crystalline semiconductor material. A second transistor is formed from the semiconductor material. The second transistor vertically stacked on the memory device.

Described is a method comprising directing an ultra-low voltage electron beam to a surface of a first insulating layer. The first insulating layer is disposed on a second insulating layer. The method includes modifying, by the application of the ultra-low voltage electron beam, the surface of the first insulating layer to selectively switch an interface between a first state having a first electronic property and a second state having a second electronic property.

An embodiment of the invention may include a first electrode, a second electrode, and a multi-level nonvolatile electrochemical cell located between the first electrode and second electrode. The multi-level nonvolatile electrochemical cell may have a read path and a write path through the cell, where the read path and the write path are different.

A semiconductor memory device including a device isolation layer in a substrate to define first and second active portions, a first contact on the substrate, first and second memory cells spaced apart from the first contact in a first direction by first and second distances, respectively, first and second conductive lines connected to the first and second memory cells, respectively, and extending in a second direction, and first and second selection transistors respectively connected to the first and second conductive lines. A length of a bottom surface of a first gate electrode of the first selection transistor overlapping the first active portion in a third direction may be different from a length of a bottom surface of a second gate electrode of the second selection transistor overlapping the second active portion in the third direction.

Disclosed herein are related to a memory cell including one or more programmable resistors and a control transistor. In one aspect, a programmable resistor includes a gate structure and one or more source/drain structures for forming a transistor. A resistance of the programmable resistor may be set by applying a voltage to the gate structure, while the control transistor is enabled. Data stored by the programmable resistor can be read by sensing current through the programmable resistor, while the control transistor is disabled. In one aspect, the one or more programmable resistors and the control transistor are implemented by same type of components, allowing the memory cell to be formed in a compact manner through a simplified the fabrication process.

This semiconductor device comprises an active layer that is formed of an oxide magnetic material and a porous dielectric body that contains water and is provided on the active layer. By using hydrogen and oxygen which are formed by electrolysis of water, the crystal structure of the active layer is changed between a ferromagnetic metal and an antiferromagnetic insulating body.

Technologies relating to crossbar array circuits with parallel ground lines are disclosed. An example crossbar array circuit may include a plurality of transistors. The crossbar array circuit may include an RRAM device connected in series with a first transistor and a second transistor; a first bit line connected to the RRAM device; and a grounding line connected to a body terminal of the first transistor. The grounding line is parallel to the first bit line. In some embodiments, the first transistor is an NMOS transistor. The second transistor is a PMOS transistor

A semiconductor structure and the fabrication method thereof are provided. The semiconductor structure includes: a substrate including a first doped region and a second doped region; a first selection transistor and a second selection transistor located in the substrate; a conductive layer located between the first doped region and the second doped region; a resistive dielectric layer located on sidewalls of the conductive layer, where the conductive layer, the first doped region, and a portion of the resistive dielectric layer facing the first doped region constitute a first variable resistor, and the conductive layer, the second doped region, and a portion of the resistive dielectric layer facing the second doped region constitute a second variable resistor; and an isolation dielectric layer located between the conductive layer and the substrate. The semiconductor structure improves the storage density of resistive random access memory (RRAM).

A method of fabricating a synaptic device is provided. The method includes forming a channel layer between a first terminal and a second terminal. The channel layer varies in resistance based on a magnesium concentration in the channel layer. The method further includes forming an electrolyte layer. The electrolyte layer includes a magnesium ion conductive material. A third terminal is formed over the electrolyte layer and applies a signal to the electrolyte layer and the channel layer.

A three terminal ReRAM device, which combines a Schottky barrier transistor and a Schottky barrier ReRAM into a single device is provided. The Schottky transistor memory device includes a source region, a drain region, and a gate electrode. Between the source and drain regions, the ReRAM material is present. The ReRAM material can include a metal oxide, such as zinc or hafnium oxide. A Schottky barrier forms naturally between the drain region and the ReRAM material. As voltage is applied to the gate electrode and the source region, the Schottky barrier breaks down, leading to the formation of a filament across the drain region and the ReRAM material. The filament is non-volatile and short-circuits the reverse-biased barrier, keeping the device in a low resistance state. The filament can be removed by reversing the polarity of the voltage such that the device switches back to a high resistance state.