The present disclosure, in some embodiments, relates to a resistive random access memory (RRAM) cell. The RRAM cell has a bottom electrode over a substrate. A data storage layer is over the bottom electrode and has a first thickness. A capping layer is over the data storage layer. The capping layer has a second thickness that is in a range of between approximately 1.9 and approximately 3 times thicker than the first thickness. A top electrode is over the capping layer.

A phase change material, a phase change memory cell, and a preparation method thereof. The phase change material comprises elements tantalum, antimony and tellurium, the phase change material having a chemical formula of Ta.sub.xSb.sub.yTe.sub.z, wherein x, y, and z represent atomic ratios of the elements respectively; and 1≤x≤25, 0.5≤y:z≤3, and x+y+z=100. The phase change thin film material Ta.sub.xSb.sub.yTe.sub.z has a high phase change speed, outstanding thermal stability, strong data retention capability, a long cycle life, and a high yield. Ta.sub.5.7Sb.sub.37.7Te.sub.56.6 has ten-year data retention capability at 165° C.; and applying same in a device cell of a phase change memory achieves an operating speed of 6 ns and endurance of more than 1 million write-erase cycles. The crystal grains of the phase change material Ta.sub.xSb.sub.yTe.sub.z of the present disclosure are small, and after annealing treatment at 400° C. for 30 minutes, the grain size is still smaller than 30 nm.

Embodiments described herein provide a gas supply system for reducing purge time and increasing processing throughput, and an atomic layer deposition (ALD) chamber having the same. The gas supply system includes an inert gas line and a precursor supply line. The inert gas line is configured to be coupled to an inlet of the chamber separate from the precursor supply line. Therefore, the inert gas is supplied concurrently to the precursor supply line and the processing region of the chamber such that total purge time is reduced. The reduction of the total purge time due to the gas supply system increases purge efficiency and increases processing throughput. Furthermore, the gas supply system allows inert gas to be utilized as a dilution gas during flow of precursors.

A projected memory device includes a carbon-based projection component. The device includes two electrodes, a memory segment, and a projection component. The projection component and the memory segment form a dual element that connects the two electrodes. The projection component extends parallel to and in contact with the memory segment. The memory segment includes a resistive memory material, while the projection component includes a thin film of non-insulating material that essentially comprises carbon. In a particular implementation, the non-insulating material and the projection component essentially comprises amorphous carbon. Using carbon and, in particular, amorphous carbon, as a main component of the projection component, allows unprecedented flexibility to be achieved when tuning the electrical resistance of the projection component.

An approach to form a semiconductor structure with a multiple layer phase change material stack and four electrodes that functions as an integrated switch device. The semiconductor structure includes a sidewall spacer that is on two opposing sides of the multiple layer phase change material stack contacting an edge of each layer of the multiple layer phase change material stack. The semiconductor structure includes a pair of a first type of electrode, where each of the pair of the first type of electrode abuts each of the sidewall spacers on the two opposing sides of the multiple layer phase change material stack. A pair of a second type of electrode, where each of the second type of electrode abuts each of two other opposing sides of the multiple layer phase change material stack and contacts a heater material on outside portions of the multiple layer phase change material stack.

A selector with a superlattice-like structure and a preparation method thereof are provided, which belong to the technical field of micro-nano electronics. The selector includes a substrate, and a first metal electrode layer, a superlattice-like layer, and a second metal electrode layer sequentially stacked on the substrate. The superlattice-like layer includes n+1 first sublayers and n second sublayers alternately stacked periodically. A material of the first sublayer is amorphous carbon, and a material of the second sublayer is a chalcogenide with gating property.

Systems, methods, and apparatus related to spike current suppression in a memory array. In one approach, a memory device includes a memory array having a cross-point memory architecture. The memory array has access lines (e.g., word lines and/or bit lines) configured to access memory cells of the memory array. Each access line has left and right portions. A conductive layer is positioned in the access line between the left and right portions. The conductive layer is formed in a socket that has been etched or otherwise formed in the access line to provide an opening. This opening is filled by the conductive layer. The conductive layer electrically connects the left and right portions of the access line to a via. A driver is electrically connected to the via for generating a voltage on the access line for accessing one or more memory cells. To reduce electrical discharge associated with current spikes, a first resistive film is formed in the access line between the left portion and the conductive layer, and a second resistive film is formed in the access line between the right portion and the conductive layer.

A method is presented for selective deposition on metals using porous low-k materials. The method includes forming alternating layers of a porous dielectric material and a first conductive material, forming a surface aligned monolayer (SAM) over the first conductive material, depositing hydroxamic acid (HA) material over the porous dielectric material, growing an oxide material over the first conductive material, removing the SAM, depositing a dielectric layer adjacent the oxide material, and replacing the oxide material with a second conductive material defining a bottom electrode.

An IC structure comprises a substrate, a first dielectric structure, a second dielectric structure, a first via structure, and a memory cell structure. The substrate comprises a memory region and a logic region. The first dielectric structure is over the memory region. The second dielectric structure laterally extends from the first dielectric structure to over the logic region. The second dielectric structure has a thickness less than a thickness of the first dielectric structure. The first via structure extends through the first dielectric structure. A top segment of the first via structure is higher than a top surface of the first dielectric structure. The first memory cell structure is over the first via structure.

Methods, devices, and systems associated with oxide based memory can include a method of forming a resistive switching region of a memory cell. Forming a resistive switching region of a memory cell can include forming a metal oxide material on an electrode and forming a metal material on the metal oxide material, wherein the metal material formation causes a reaction that results in a graded metal oxide portion of the memory cell.