The present application provides an apparatus, including: a substrate; a first line electrode formed on the substrate; an interlayer formed on the first line electrode, a selector stack formed on the interlayer and the first line electrode; an RRAM stack formed on the selector stack; and a second line electrode formed on the RRAM stack. The interlayer comprises an upper surface and a sidewall. In some embodiments, a shape of the interlayer comprises a cylinder, a pyramid, a prism, a cone, a pillar, or a protrusion;

Numerous embodiments of circuitry for a set-while-verify operation and a reset-while verify operation for resistive random access memory cells are disclosed. In one embodiment, a set-while-verify circuit for performing a set operation on a selected RRAM cell in the array applies a combination of voltages or current to a bit line, word line, and source line associated with the selected RRAM cell and stops said applying when the set operation is complete. In another embodiment, a reset-while-verify circuit for performing a reset operation on a selected RRAM cell in the array applies a combination of voltages or current to a bit line, word line, and source line associated with the selected RRAM cell and stops said applying when the reset operation is complete.

A memristor includes a bottom electrode, a top electrode, and an active region disposed therebetween. The active region has an electrically conducting filament in an electrically insulating medium, extending between the bottom electrode and the top electrode. The memristor further includes a temperature gradient element for controlling switching.

Provided are embodiments for method of fabricating a dual damascene crossbar array. The method includes forming a bottom electrode layer on a substrate and forming a first memory device on the bottom electrode layer. The method also includes forming a dual damascene structure on the first memory device, wherein the dual damascene structure includes a top electrode layer and a first via, wherein the first via is formed between the first memory device and the top electrode layer. Also provided are embodiments for the dual damascene crossbar and embodiments for disabling memory devices of the dual damascene crossbar array.

A phase change memory includes a phase change structure. There is a heater coupled to a first surface of the phase change structure. A first electrode is coupled to a second surface of the phase change structure. A second electrode coupled to a second surface of the heater. A third electrode is connected to a first lateral end of the phase change structure and a fourth electrode connected to a second lateral end of the phase change structure.

Methods, systems, and devices for memory cells with asymmetrical electrode interfaces are described. A memory cell with asymmetrical electrode interfaces may mitigate shorts in adjacent word lines, which may be leveraged for accurately reading a stored value of the memory cell. The memory device may include a self-selecting memory component with a top surface area in contact with a top electrode and a bottom surface area in contact with a bottom electrode, where the top surface area in contact with the top electrode is a different size than the bottom surface area in contact with the bottom electrode.

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.

A method for producing a memory device includes depositing a second interlayer insulating film on a substrate, forming contact holes, and depositing a second metal and a nitride film. The second metal and the nitride film are removed to form pillar-shaped nitride layers, and to form lower electrodes surrounding the pillar-shaped nitride layers. The second interlayer insulating film is etched back to expose upper portions of the lower electrodes. The upper portions of the lower electrodes surrounding the pillar-shaped nitride film are removed and a phase change film is deposited to surround the pillar-shaped nitride film and connect with the lower electrodes. The phase change film is etched on upper portions of the pillar-shaped nitride film, and a reset gate insulating film is formed surrounding the phase change film and forming a reset gate having a side wall shape and remaining on the upper portions of the pillar-shaped nitride film.

The present disclosure relates to an integrated circuits device having an RRAM cell, and an associated method of formation. In some embodiments, the integrated circuit device has a lower metal interconnect line disposed within a lower inter-level dielectric (ILD) layer and an upper metal interconnect line disposed within an upper inter-level dielectric (ILD) layer. The integrated circuit device also has a memory cell array disposed between the lower metal interconnect line and the upper metal interconnect line, including memory cells arranged in rows and columns, the memory cells respectively includes a bottom electrode and a top electrode separated by a RRAM dielectric having a variable resistance. A bottom contact structure is disposed on the lower metal interconnect line and along sidewalls of the bottom electrode, electrically coupling the lower metal interconnect line and the bottom electrode.

To provide enhanced data storage devices and systems, various systems, architectures, apparatuses, and methods, are provided herein. In a first example, a resistive random access memory (ReRAM) array is provided. The ReRAM array includes a plurality of memory cells each comprising resistive memory material formed into a layer of a substrate, with resistance properties of the resistive memory material corresponding to data bits stored by the memory cells. The ReRAM array also includes a plurality of interconnect features each comprising conductive material between adjacent memory cells formed into the layer of the substrate, and gate portions coupled onto the memory cells and configured to individually alter the resistance properties of the resistive memory material of associated memory cells responsive to at least voltages applied to the gate portions.