Some embodiments relate to a method for forming an integrated chip. The method includes forming a bottom electrode over a substrate. A data storage layer is formed on the bottom electrode. A diffusion barrier layer is formed over the data storage layer. The diffusion barrier layer has a first diffusion activation temperature. A top electrode is formed over the diffusion barrier layer. The top electrode has a second diffusion activation temperature less than the first diffusion activation temperature.

A semiconductor device structure is provided. The structure includes a semiconductor substrate and a data storage element over the semiconductor substrate. The structure also includes an ion diffusion barrier element over the data storage element and a protective element extending along a sidewall of the ion diffusion barrier element. A bottom surface of the protective element is between a top surface of the data storage element and a bottom surface of the data storage element. The structure further includes a first electrode electrically connected to the data storage element and a second electrode electrically connected to the data storage element.

A plurality of memory cells in a cross-point array in which the memory cell stacks in the cross-points include a switch element, a conductive barrier layer, and a confined cell structure in series, and having sides aligned within the cross-point area of the corresponding cross-point, the confined cell structure including surfactant spacers within the cross-point area having outside surfaces on a pair of opposing sides of the stack, and a body of programmable resistance memory material confined between inside surfaces of the surfactant spacers. The memory cells can be operated as multi-level cells in a 3D array.

A first phase change material layer vertically aligned above a bottom electrode, a dielectric layer vertically aligned above the first phase change material layer, a second phase change material layer vertically aligned above the dielectric layer, an inner electrode physically and electrically connected to the first phase change material layer and the second phase change material layer, the inner electrode surrounded by the dielectric layer, a top electrode vertically aligned above the second phase change material layer. A first phase change material layer vertically aligned above a bottom electrode, a filament layer vertically aligned above the first phase change material layer, a second phase change material layer vertically aligned above the filament layer, an inner break in the filament layer connecting the first phase change material layer and the second phase change material layer, a top electrode vertically aligned above the second phase change material layer.

Provided is a method of manufacturing a resistive random access memory (RRAM) including: forming a lower electrode protruding from a top surface of a dielectric layer; conformally forming a data storage layer on the lower electrode and the dielectric layer; forming an oxygen reservoir material layer on the data storage layer; forming an opening in the oxygen reservoir material layer to expose the data storage layer on the lower electrode; forming an isolation structure in the opening, wherein the isolation structure divides the oxygen reservoir material layer into a first oxygen reservoir layer and a second oxygen reservoir layer; and forming an upper electrode on the first and second oxygen reservoir layers, wherein the first and second oxygen reservoir layers share the upper electrode.

A semiconductor device includes a first electrode and a first carbon layer on the first electrode. A switch layer is disposed on the first carbon layer and a second carbon layer is disposed on the switch layer. At least one tunneling oxide layer is disposed between the first carbon layer and the second carbon layer. The device further includes a second electrode on the second carbon layer.

A semiconductor device and method of forming a semiconductor device are provided. The semiconductor device includes a pore-type heater having a center pore recess. The semiconductor device further includes a tapered structure formed on the pore-type heater and having a tip portion at least extending down to the center pore recess. The semiconductor device also includes a containment layer confining volatile active material during any of a fabrication and an operation of the semiconductor device performed above a threshold temperature.

Methods, systems, and devices for a resistive interface material are described. A memory device may be fabricated using a sequence of steps that include forming a stack of materials by depositing a first metal layer, depositing a first electrode layer on the metal layer, depositing a memory material on the first electrode layer to form one or more memory cells, depositing a second electrode layer on the memory material, and depositing a second metal layer on the second electrode layer. A lamina (or multiple) having a relatively high resistivity may be included in the stack of materials to reduce or eliminate a current spike that may otherwise occur across the memory cells during an access operation.

According to an embodiment, a phase-change memory device comprises: an upper electrode and a lower electrode; a phase-change layer in which a crystal state thereof is changed by heat supplied by the upper electrode and the lower electrode; and a selector which selectively switches the heat supplied by the upper electrode and the lower electrode to the phase-change layer, wherein the selector is formed of a compound which includes a transition metal in the phase-change material so as to have a high resistance when the crystalline state of the selector is crystalline and so as to have a low resistance when the crystalline state of the selector is non-crystalline.

A semiconductor structure includes a first electrode comprising a first metallic material; a memory film including at least one dielectric metal oxide material and contacting the first electrode; and a second electrode comprising a second metallic material and contacting the memory film. The memory film includes a center region having a first average atomic ratio of a passivation element to oxygen that is less than 0.01, and includes a peripheral region having a second average atomic ratio of the passivation element to oxygen that is greater than 0.05.