An information processing device, including a resistive analog neuromorphic device element having a pair of electrodes and an oxide layer provided between the pair of electrodes, and a parallel circuit having a low resistance component and a capacitance component. The parallel circuit and the resistive analog neuromorphic device element are connected in series.

A semiconductor memory device includes a substrate having a first interlayer dielectric layer thereon; a lower metal interconnect layer in the first interlayer dielectric layer; a conductive via disposed on the lower metal interconnect layer; a bottom electrode disposed on the conductive via; a dielectric data storage layer having variable resistance disposed on the bottom electrode; a top electrode disposed on the dielectric data storage layer; and a protective layer covering sidewalls of the top electrode, the dielectric data storage layer, and the bottom electrode. The protective layer includes an annular, upwardly protruding portion around a perimeter of the top electrode.

The invention provides a microelectronic device comprising at least two memory cells each comprising a so-called selection transistor and a memory element associated with said selection transistor, each transistor comprising a channel in the form of a wire extending in a first direction (x), a gate bordering said channel, a source extending in a second direction (y), and a drain connected to the memory element, said transistors being stacked in a third direction (z) and each occupying a given altitude level in the third direction (z), the microelectronic device wherein the source and the drain are entirely covered by spacers projecting in the third direction (z) in a plane (xy). The invention also provides a method for manufacturing such a device.

Technologies relating to increasing the surface area of selectors in crossbar array circuits are provided. An example apparatus includes: a substrate; a first line electrode formed on the substrate; an RRAM stack formed on the first line electrode, wherein the RRAM stack; an isolation layer formed beside the RRAM stack, wherein the isolation layer includes an upper surface and a sidewall, and a height from the upper surface to the first line electrode is 100 nanometers to 10 micrometers; a selector stack formed on the RRAM stack, the sidewall, and the upper surface; and a second line electrode formed on the selector stack.

A resistive RAM module comprises a source electrode and an intermediate electrode that is formed on the source electrode. The intermediate electrode has a closed-curve profile. The resistive RAM module also comprises a memristor element that is deposited on the intermediate electrode. The resistive RAM module also comprises a sink electrode that is in contact with the memristor element. The intermediate electrode is electrically between the source electrode and the memristor element and the memristor element is electrically between the intermediate electrode and the sink electrode.

A RRAM device includes a bottom electrode, a resistive material layer, a high work function layer, a top electrode, a hard mask and high work function sidewall parts. The bottom electrode, the resistive material layer, the high work function layer, the top electrode and the hard mask are sequentially stacked on a substrate. The high work function sidewall parts cover sidewalls of the top electrode and sidewalls of the hard mask, thereby constituting a RRAM cell. A method of forming said RRAM device is also provided.

Provided is a memory device including a stack structure, a plurality of channel layers, a source line, a bit line, a switching layer, and a dielectric pillar. The stack structure has a plurality of dielectric layers and a plurality of conductive layers stacked alternately. The channel layers are respectively embedded in the conductive layers. The source line penetrates through the stack structure to be electrically connected to the channel layers at first sides of the channel layers. The bit line penetrates through the stack structure to be coupled to the channel layers at second sides of the channel layers. The switching layer wraps the bit line to contact the channel layers at the second sides of the channel layers. The dielectric pillar penetrates through the channel layers to divide each channel layer into a doughnut shape. A method of manufacturing a memory device is also provided.

An electronic device comprises a semiconductor memory that includes: a memory cell; a protective layer disposed along a profile of the memory cell; and a buffer layer interposed between at least a portion of a sidewall of the memory cell and the protective layer, wherein the buffer layer and the protective layer include silicon nitride, and wherein a density of the protective layer is greater than a density of the buffer layer.

A memory cell includes: a resistive material layer comprising a first portion that extends along a first direction and a second portion that extends along a second direction, wherein the first and second directions are different from each other; a first electrode coupled to a bottom surface of the first portion of the resistive material layer; and a second electrode coupled to the second portion of the resistive material layer.

Provided is an electronic device including a first electrode; a second electrode facing the first electrode; and an active layer between the first electrode and the second electrode, wherein at least one of the first electrode and the second electrode includes a first surface that is closest to the active layer and a second surface that is farthest from the active layer, a size of a cross-sectional horizontal area at the first surface is smaller than a size of a cross-sectional horizontal area at the second surface, the active layer includes a first region, which vertically overlaps the first surface, and a second region outside the first region, and a thickness of the active layer in the first region is smaller than a thickness of the active layer in the second region.