A phase change memory includes an L-shaped resistive element having a first part that extends between a layer of phase change material and an upper end of a conductive via and a second part that rests at least partially on the upper end of the conductive via and may further extend beyond a peripheral edge of the conductive via. The upper part of the conductive via is surrounded by an insulating material that is not likely to adversely react with the metal material of the resistive element.

A memory device includes a first electrode line layer including a plurality of first electrode lines extending on a substrate in a first direction and being spaced apart from each other, a second electrode line layer including a plurality of second electrode lines extending on the first electrode line layer in a second direction that is different from the first direction and being spaced apart from each other, and a memory cell layer including a plurality of first memory cells located at a plurality of intersections between the plurality of first electrode lines and the plurality of second electrode lines, each first memory cell including a selection device layer, an intermediate electrode and a variable resistance layer that are sequentially stacked. A side surface of the variable resistance layer is perpendicular to a top surface of the substrate or inclined to be gradually wider toward an upper portion of the variable resistance layer. The first memory cell has a side surface slope so as to have a width gradually decreasing toward its upper portion.

A phase change memory array and method for fabricating the same. The phase change memory array includes a plurality of bottom electrodes, top electrodes, and memory pillars. Each of the memory pillars includes phase change material surrounded by a dielectric casing. The phase change material is positioned between, and in series circuit with, a respective bottom electrode from the bottom electrodes and a respective top electrode from the top electrodes. A continuous layer of selector material is positioned between the memory pillars and the plurality of bottom electrodes. The selector material is configured to conduct electricity only when a voltage across the selector material exceeds a voltage threshold.

A semiconductor structure includes a substrate and a phase-change memory cell located on the substrate. The phase-change memory cell includes a phase-change material layer and a heating layer. The heating layer is located between the phase-change material layer and the substrate, and includes a first portion composed of a first conductive material and a second portion composed of a second conductive material. The first portion surrounds at least a sidewall of the second portion.

A method for fabricating a semiconductor device includes forming air gaps within respective dielectric layer portions to reduce thermal cross-talk between adjacent bits. Each of the dielectric portions is formed on a substrate each adjacent to sidewall liners formed on sidewalls of a phase change memory (PCM) layer. The method further includes forming a pillar including the sidewall liners and the PCM layer, and forming a selector layer on the pillar and the dielectric portions.

A phase change memory (PCM) cell with enhanced thermal isolation and low power consumption is provided. In some embodiments, the PCM cell comprises a bottom electrode, a dielectric layer, a heating element, and a phase change element. The dielectric layer is on the bottom electrode. The heating element extends through the dielectric layer, from a top of the dielectric layer to the bottom electrode. Further, the heating element has a pair of opposite sidewalls laterally spaced from the dielectric layer by a cavity. The phase change element overlies and contacts the heating element. An interface between the phase change element and the heating element extends continuously respectively from and to the opposite sidewalls of the heating element. Also provided is a method for manufacturing the PCM cell.

A memory cell includes a heating element topped with a phase-change material. Two first silicon oxide regions laterally surround the heating element along a first direction. Two second silicon oxide regions laterally surround the heating element along a second direction orthogonal to the first direction. Top surfaces of the heating element and the two first silicon oxide regions are coplanar such that the heating element and the two first silicon oxide regions have a same thickness.

The technology of a crossbar array circuit and method of improving thermal shielding are disclosed. An example apparatus includes a bottom wire; a first vertical thermal shielding layer formed on the bottom wire, a bottom electrode formed on the first vertical thermal shielding layer; a filament forming layer formed on the bottom electrode; a top electrode formed on the filament forming layer; a second vertical thermal shielding layer formed on the top electrode; a top wire formed on the second vertical thermal shielding layer, wherein the filament forming layer is configured to form a filament within the filament forming layer when applying a switching voltage upon the filament forming layer, and wherein a material of the first vertical thermal shielding layer and the second vertical thermal shielding layer includes ReO.sub.x, RuO.sub.x, IrO.sub.x, ITO, a combination thereof, or an alloy or doping thereof (with or without other thermally conductive materials).

In some embodiments, the present disclosure relates to an integrated chip including a phase change material disposed over a bottom electrode and configured to change from a crystalline structure to an amorphous structure upon temperature changes. A top electrode is disposed over an upper surface of the phase change material. A via electrically contacts a top surface of the top electrode. Further, a maximum width of the upper surface of the phase change material is less than a maximum width of a bottom surface of the phase change material.

Methods, systems, and devices for a three-dimensional memory array are described. Memory cells may transform when exposed to elevated temperatures, including elevated temperatures associated with a read or write operation of a neighboring cell, corrupting the data stored in them. To prevent this thermal disturb effect, memory cells may be separated from one another by thermally insulating regions that include one or several interfaces. The interfaces may be formed by layering different materials upon one another or adjusting the deposition parameters of a material during formation. The layers may be created with planar thin-film deposition techniques, for example.