A method of forming an array of memory cells includes forming lines of covering material that are elevationally over and along lines of spaced sense line contacts. Longitudinal orientation of the lines of covering material is used in forming lines comprising programmable material and outer electrode material that are between and along the lines of covering material. The covering material is removed over the spaced sense line contacts and the spaced sense line contacts are exposed. Access lines are formed. Sense lines are formed that are electrically coupled to the spaced sense line contacts. The sense lines are angled relative to the lines of spaced sense line contacts and relative to the access lines. Other embodiments, including structure independent of method, are disclosed.

A memory cell can include a top lamina layer, a bottom lamina layer, and a phase change material (PCM) layer between the top lamina layer and the bottom lamina layer. The PCM layer can have a top surface in direct contact with the top lamina layer and a bottom surface in direct contact with the bottom lamina layer. The top surface of the PCM layer and the bottom surface of the PCM layer can have a structurally stabilizing width ratio.

The present disclosure relates to a memory device. The memory device includes a first electrode over a substrate and a second electrode over the substrate. A data storage structure is disposed between the first electrode and the second electrode. The data storage structure includes one or more metals having non-zero concentrations that change as a distance from the substrate increases.

A selector device intended to select a resistive memory cell includes a first selector device including a first active material and a second selector device including a second active material, the first selector device and the second selector device being connected in parallel.

A cross-bar ReRAM comprising a substrate, a plurality of first columns extending parallel to each other on the top surface of the substrate, wherein each of the plurality of the first columns includes a resistive random-access memory (ReRAM) stack comprised of a plurality of layers. A plurality of second columns extending parallel to each other and the plurality of second columns extending perpendicular to the plurality of first columns, wherein the plurality of second columns is located on top of the plurality of first columns, such that the plurality of second columns crosses over the plurality of first columns. A dielectric layer filling in the space between the plurality of first columns and the plurality of second columns, wherein the dielectric layer is in direct contact with a sidewall of each of the plurality layers of the ReRAM stack.

The superior electronic and mechanical properties of 2D-layered transition metal dichalcogenides and other 2D layered materials could be exploited to make a broad range of devices with attractive functionalities. However, the nanofabrication of such layered-material-based devices still needs resist-based lithography and plasma etching processes for patterning layered materials into functional device features. Such patterning processes lead to unavoidable contaminations, to which the transport characteristics of atomically-thin layered materials are very sensitive. More seriously, such lithography-introduced contaminants cannot be safely eliminated by conventional material wafer cleaning approaches. This disclosure introduces a rubbing-induced site-selective growth method capable of directly generating few-layer molybdenum disulfide device patterns without the need of any additional patterning processes. This method consists of two critical steps: (i) a damage-free mechanical rubbing process for generating microscale triboelectric charge patterns on a dielectric surface, and (ii) site-selective deposition of molybdenum disulfide or the like within rubbing-induced charge patterns.

The present disclosure relates to a resistive random access memory (RRAM) device. The RRAM device includes a first electrode over a substrate and a second electrode over the substrate. A data storage structure is disposed between the first electrode and the second electrode. The data storage structure includes a first metal and a second metal. The first metal has a peak concentration at a first distance from the first electrode and the second metal has a peak concentration at a second distance from the first electrode. The first distance is different than the second distance.

Provided are a memory cell and a method of forming the same. The memory cell includes a bottom electrode, a top electrode, a storage element layer, and a protective layer. The storage element layer is disposed between the bottom and top electrodes. The protective layer covers the storage element layer and the top electrode, and a material of the protective layer is derived from the storage element layer. A semiconductor device having the memory cell is also provided.

The disclosed subject matter relates generally to memory devices and a method of forming the same. More particularly, the present disclosure relates to resistive random-access (ReRAM) memory devices. The present disclosure provides a memory device including a first electrode having tapered sides that converge at a top of the first electrode, a dielectric layer disposed on and conforming to the tapered sides of the first electrode, a resistive layer in contact with the top of the first electrode and the dielectric layer, and a second electrode disposed on the resistive layer.

A resistive random access memory cell includes a gate all around transistor and a resistor device. The resistor device includes a first electrode including a plurality of conductive nanosheets. The resistor device includes a high-K resistive element surrounds the conductive nanosheets. The resistor device includes a second electrode separated from the conductive nanosheets by the resistive element.