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 resistive random access memory includes a memory cell disposed at an intersection point between a first conductive line and a second conductive line. The memory cell includes a selector structure, a first current limiter structure and a resistor structure. The first current limiter structure is disposed between the selector structure and the first conductive line. The resistor structure is disposed between the selector structure and the second conductive line or between the first current limiter structure and the first conductive line.

A semiconductor structure includes a plurality of stack structures overlying a substrate. Each stack structure includes a first chalcogenide material over a conductive material overlying the substrate, an electrode over the first chalcogenide material, a second chalcogenide material over the electrode, a liner on sidewalls of at least one of the first chalcogenide material or the second chalcogenide material, and a dielectric material over and in contact with sidewalls of the electrode and in contact with the liner. Related semiconductor devices and systems, methods of forming the semiconductor structure, semiconductor device, and systems, and methods of forming the liner in situ are disclosed.

A switch device includes a first electrode, a second electrode, and a switch layer. The second electrode is disposed to face the first electrode. The switch layer is provided between the first electrode and the second electrode. The switch layer contains an amorphous material made of at least germanium (Ge) and one of nitrogen (N) and oxygen (O).

To provide enhanced data storage devices and systems, various systems, architectures, apparatuses, and methods, are provided herein. In a first example, a resistive memory device is provided. The resistive memory device includes an active region having resistance properties that can be modified to store one or more data bits in the resistive memory device, and at least one sidewall portion of the active region comprising a dopant configured to suppress conductance paths in the active region proximate to the at least one sidewall portion. The resistive memory device includes terminals configured to couple the active region to associated electrical contacts.

A resistive random access memory overcomes the low durability of the conventional resistive random access memory. The resistive random access memory includes a first electrode, a second electrode, an enclosing layer and an oxygen-containing resistance changing layer. The first and second electrodes are separate from each other. The enclosing layer forms a first via-hole. The oxygen-containing resistance changing layer is arranged for the first via-hole. The first and second electrodes and the enclosing layer jointly enclose the oxygen-containing resistance changing layer. Each of the first electrode, the second electrode and the enclosing layer is made of an element not containing oxygen.

A resistive memory device includes a first electrode, a sidewall spacer electrode located on a sidewall of a dielectric material contacting the first electrode, a resistive memory cell containing a resistive memory material and contacting the sidewall spacer electrode, and a second electrode containing the resistive memory cell.

Some embodiments include memory structures having a diode over a memory cell. The memory cell can include programmable material between a pair of electrodes, with the programmable material containing a multivalent metal oxide directly against a high-k dielectric. The diode can include a first diode electrode directly over one of the memory cell electrodes and electrically coupled with the memory cell electrode, and can include a second diode electrode laterally outward of the first diode electrode and not directly over the memory cell. Some embodiments include memory arrays comprising the memory structures, and some embodiments include methods of making the memory structures.

A memory using mixed valence conductive oxides is disclosed. The memory includes a mixed valence conductive oxide that is less conductive in its oxygen deficient state and a mixed electronic ionic conductor that is an electrolyte to oxygen and promotes an electric filed to cause oxygen ionic motion.

A memory device includes: a memory layer that is isolated for each memory cell and stores information by a variation of a resistance value; an ion source layer that is formed to be isolated for each memory cell and to be laminated on the memory layer, and contains at least one kind of element selected from Cu, Ag, Zn, Al and Zr and at least one kind of element selected from Te, S and Se; an insulation layer that isolates the memory layer and the ion source layer for each memory cell; and a diffusion preventing barrier that is provided at a periphery of the memory layer and the ion source layer of each memory cell to prevent the diffusion of the element.