A device including a reduced top RRAM electrode structure, and method of production thereof. Embodiments include a bottom resistive random-access memory (RRAM) electrode structure over a plurality of lower metal level contact formed laterally separated in a substrate; a resistive switching structure over the bottom RRAM electrode structure; a top RRAM electrode structure over the resistive switching structure; a protective structure over the top RRAM electrode structure; an encapsulation structure over the bottom RRAM electrode structure and on sidewalls of the resistive switching structure, the top RRAM electrode structure and the protective structure; and an Nblock layer over the substrate.

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 method is presented for incorporating a resistive random access memory (RRAM) stack within a resistive memory crossbar array. The method includes forming a conductive line within an interlayer dielectric (ILD), constructing a barrier layer over a portion of the conductive line, forming a bottom meshed electrode, depositing a dielectric layer over the bottom meshed electrode, and forming a top meshed electrode over the dielectric layer, where each of the top and bottom meshed electrodes includes a plurality of isolations films.

A method is presented for incorporating a resistive random access memory (RRAM) stack within a resistive memory crossbar array. The method includes forming a conductive line within an interlayer dielectric (ILD), constructing a barrier layer over a portion of the conductive line, forming a bottom meshed electrode, depositing a dielectric layer over the bottom meshed electrode, and forming a top meshed electrode over the dielectric layer, where each of the top and bottom meshed electrodes includes a plurality of isolations films.

A method of fabricating a phase change material (PCM) device is provided. The method includes disposing a dielectric layer above or below a PCM layer and disposing first and second contacts in a same plane within the dielectric layer with the first contact having a larger contact area than the second contact. The method also includes one of directing a short current pulse from the first contact to the second contact so as to form amorphous-PCM in a region of the PCM layer adjacent to the second contact with crystalline-PCM partially surrounding and in contact with the amorphous-PCM and directing a long current pulse from the first contact to the second contact so as to form crystalline-PCM in the region of the PCM layer adjacent to the second contact.

A method for manufacturing a semiconductor memory device includes forming a bottom electrode on a bottom contact layer, and forming a dielectric layer covering sides of the bottom electrode. In the method, a switching element layer is deposited on the dielectric layer and the bottom electrode, a top electrode layer is deposited on the switching element layer, and a hardmask layer is deposited on the top electrode layer. The switching element, top electrode and hardmask layers are patterned into a pillar on the bottom electrode. The method further includes forming a spacer layer on the dielectric layer on sides of the pillar, and forming a metal layer on the dielectric layer adjacent the spacer layer and around the pillar.

The present disclosure includes memory cell structures and method of forming the same. One such memory cell includes a first electrode having sidewalls angled less than 90 degrees in relation to a bottom surface of the first electrode, a second electrode, including an electrode contact portion of the second electrode, having sidewalls angled less than 90 degrees in relation to the bottom surface of the first electrode, wherein the second electrode is over the first electrode, and a storage element between the first electrode and the electrode contact portion of the second electrode.

A memory cell pillar of a memory device includes a heating electrode having a base portion (leg) and a fin portion (ascender), and a selection device between a first conductive line and the heating electrode. A side surface of the selection device and a side surface of the fin portion extend along a first straight line. A method of fabricating a memory device includes forming a plurality of first insulating walls through a stack structure including a preliminary selection device layer and a preliminary electrode layer, forming a plurality of self-aligned preliminary heating electrode layers, forming a plurality of second insulating walls each between two of the plurality of first insulating walls, and forming a plurality of third insulating walls in a plurality of holes extending along a direction intersecting the plurality of first insulating walls.

A memory device including a lower electrode having an upper portion extending above an upper surface of a first dielectric layer, wherein the upper portion of the lower electrode has corners that are exposed. The memory device also includes a metal oxide layer having a conformal thickness present on sidewalls of the upper portion of the lower electrode. The metal oxide layer is present on at least the corners of the lower electrode that extend above the first dielectric layer. The memory device may also include an upper electrode present on the metal oxide layer. The upper electrode being separated from an entirety of the lower electrode by the metal oxide layer. In some embodiments, the memory device is a resistive random access memory device. The corners of the lower electrode localize filament formation in the metal oxide layer.

A semiconductor structure includes an oxide ReRAM co-integrated with a drain region of a field effect transistor (FET). The oxide ReRAM has a tip region defined by a pointed cone that contacts a faceted upper surface of the drain region of the FET. Such a tip region enhances the electric field of the oxide ReRAM and thus helps to control forming of the conductive filament of the oxide ReRAM.