A memory device includes a transistor, a memory cell, and an interconnect layer. The transistor includes a bottom source/drain portion, a channel portion, and a top source/drain portion stacked from bottom to top and a gate structure surrounding the channel portion. The memory cell includes a nanowire bottom electrode, a first dielectric layer, a second dielectric layer, and a top electrode. The first dielectric layer laterally surrounds the nanowire bottom electrode. The second dielectric layer is over the nanowire bottom electrode and the first dielectric layer. The second dielectric layer is in contact with a top surface of the nanowire bottom electrode and a sidewall of the first dielectric layer. The top electrode covers the second dielectric layer. The interconnect layer is over the transistor and the memory cell to interconnect the transistor and the memory cell.

A phase change memory (PCM) structure configured for performing a gradual reset operation includes first and second electrodes and a phase change material layer disposed between the first and second electrodes. The PCM structure further includes a thermal insulation layer disposed on at least sidewalls of the first and second electrodes and phase change material layer. The thermal insulation layer is configured to provide non-uniform heating of the phase change material layer. Optionally, the thermal insulation layer may be formed as an air gap. The PCM structure may be configured having the first and second electrodes aligned in a vertical or a lateral arrangement.

A semiconductor device includes a diffusion barrier structure, a bottom electrode, a top electrode, a switching layer and a capping layer. The bottom electrode is over the diffusion barrier structure. The top electrode is over the bottom electrode. The switching layer is between the bottom electrode and the top electrode, and configured to store data. The capping layer is between the switching layer and the top electrode. The diffusion barrier structure includes a multiple-layer structure. A thermal conductivity of the diffusion barrier structure is greater than approximately 20 W/mK.

A method includes providing a substrate having a main surface, forming a layer of thermally insulating material on the main surface, forming strips of phase change material on the layer of thermally insulating material such that strips of phase change material are separated from the main surface by thermally insulating material, forming first and second RF terminals on the main surface that are laterally spaced apart from one another and connected to the strips of phase change material, and forming a heater structure having heating elements that are configured to control a conductive connection between the first and second RF terminals by applying heat to the one or more strips of phase change material, wherein each of the strips of phase change material includes multiple outer faces, and wherein portions of both outer faces from the strips of phase change material are disposed against one of the heating elements.

A phase-change memory device includes a bottom electrode; a stack of alternating electrical conductor layers directly contacting a top surface of the bottom electrode; a metal pillar directly contacting a top surface of the stack; a phase change material element directly contacting a top surface of the metal pillar; and a top electrode on the phase change material element, wherein a lateral dimension of the metal pillar is smaller than that of the stack.

A hybrid switch and memory cell includes a transistor device that has an atomically-thin semiconductor material channel, source/drain electrodes, and gate dielectric. The cell includes a resistive-random-access-memory having a thin conductive edge and a 2D insulator layer over the thin conductive edge, wherein the 2D insulator layer extends over the semiconductor channel and serves as the gate dielectric in the transistor device.

A method for producing a resistive memory cell from a stack of layers having a metal-oxide layer interleaved between first and second electrodes includes forming, within one from among the first and second electrodes, an interlayer material-based electrode interlayer having a selectivity to etching greater than or equal to 2:1 relative to materials of the electrodes. During an etching of the stack, overetching is performed configured to laterally consume, in a horizontal direction, the interlayer material such that the electrode interlayer has a lateral recess greater than or equal to 10 nm.

The present disclosure relates to a chalcogenide material including germanium (Ge) with a first atomic percent, selenium (Se) with a second atomic percent that is at least twice the first atomic percent of the germanium, and indium (In) with a third atomic percent less the first atomic percent of the germanium.

A memory cell includes a first conductive line, a lower electrode, a carbon nano-tube (CNT) layer, a middle electrode, a resistive layer, a top electrode and a second conductive line. The first conductive line is disposed over a substrate. The lower electrode is disposed over the first conductive line. The carbon nano-tube (CNT) layer is disposed over the lower electrode. The middle electrode is disposed over the carbon nano-tube layer, thereby the lower electrode, the carbon nano-tube (CNT) layer and the middle electrode constituting a nanotube memory part. The resistive layer is disposed over the middle electrode. The top electrode is disposed over the resistive layer, thereby the middle electrode, the resistive layer and the top electrode constituting a resistive memory part. The second conductive line is disposed over the top electrode.

An RRAM structure includes a substrate. The substrate is divided into a memory cell region and a logic device region. A metal plug is disposed within the memory cell region. An RRAM is disposed on and contacts the metal plug. The RRAM includes a top electrode, a variable resistive layer, and a bottom electrode. The variable resistive layer is disposed between the top electrode and the bottom electrode. The variable resistive layer includes a first bottom surface. The bottom electrode includes a first top surface. The first bottom surface and the first top surface are coplanar. The first bottom surface only overlaps and contacts part of the first top surface.