Disclosed in Disclosed are a resistive random access memory and a manufacturing method. A memory area of the resistive random access memory comprises a first metal interconnection line, a resistive random access memory unit and a second metal interconnection line that are connected in sequence, wherein the whole or part of a bottom electrode of the resistive random access memory unit is arranged in a short through hole of a barrier layer on the first metal interconnection line; the first metal interconnection line is connected to the bottom electrode of the resistive random access memory unit; and the second metal interconnection line is connected to a top electrode of the resistive random access memory unit. By means of arranging the whole or part of the bottom electrode of the resistive random access memory unit in the short through hole of the barrier layer on the first metal interconnection line, the bottom electrode can be made to be very thin, such that the height of the resistive random access memory unit in a CMOS back end of line is reduced, the thickness, which needs to be occupied, of each layer in the CMOS back end of line is smaller, integration is facilitated, the back end of line of a logic circuit area cannot be influenced, and the total stacking thickness can meet the electrical property requirement of the resistive random access memory. The process integration scheme in the embodiments of the present application can make the integration of an RRAM and a standard CMOS simpler.

Provided are a switching device and a memory device including the switching device. The switching device includes first and second electrodes, and a switching material layer provided between the first and second electrodes and including a chalcogenide. The switching material layer includes a core portion and a shell portion covering a side surface of the core portion. The switching layer includes a material having an electrical resistance greater than an electrical resistance of the core portion, for example in at least one of the core portion or the shell portion.

A semiconductor device is provided. The semiconductor device includes a substrate a substrate, a first electrode structure on the substrate, the first electrode structure including first insulating patterns and first electrode patterns, the first insulating patterns alternately stacked with the first electrode patterns, a second electrode pattern on a sidewall of the first electrode structure, and a data storage film on a sidewall of the second electrode pattern. The data storage film has a variable resistance.

The problem of forming top electrode vias that provide consistent results in devices that include resistance switching RAM cells of varying heights is solved using a dielectric composite that fills areas between resistance switching RAM cells and varies in height to align with the tops of both the taller and the shorter resistance switching RAM cells. An etch stop layer may be formed over the dielectric composite providing an equal thickness of etch-resistant dielectric over both taller and shorter resistance switching RAM cells. The dielectric composite causes the etch stop layer to extend laterally away from the resistance switching RAM cells to maintain separation between the via openings and the resistance switching RAM cell sides even when the openings are misaligned.

In the examples provided herein, an electrostatic discharge (ESD) recording circuit has a first memristive element coupled to a pin of an integrated circuit. The first memristive element switches from a first resistance to a second resistance when an ESD event occurs at the pin, and the first resistance is less than the second resistance. The ESD recording circuit also has shunting circuitry to shunt energy from an additional ESD event away from the first memristive element.

An improved switching material for forming a composite article over a substrate is disclosed. A first volume of nanotubes is combined with a second volume of nanoscopic particles in a predefined ration relative to the first volume of nanotubes to form a mixture. This mixture can then be deposited over a substrate as a relatively thick composite article via a spin coating process. The composite article may possess improved switching properties over that of a nanotube-only switching article. A method for forming substantially uniform nanoscopic particles of carbon, which contains one or more allotropes of carbon, is also disclosed.

A plurality of memory cells in a 3D cross-point array with improved endurance is disclosed. Each memory cell, disposed between first and second conductors, includes a switch in series with a pillar of phase change material. The pillar has a Te-rich material at one end proximal to the second conductor, and an Sb-rich material at the other end proximal to the first conductor, wherein the current direction is from the first conductor to the second conductor.

An aspect of the invention relates to an elementary cell that includes a breakdown layer made of dielectric having a thickness that depends on a breakdown voltage, a device and a non-volatile resistive memory mounted in series, the device including an upper selector electrode, a lower selector electrode, a layer made in a first active material, referred to as active selector layer, the device being intended to form a volatile selector; the memory including an upper memory electrode, a lower memory electrode, a layer made in at least one second active material, referred to as active memory layer.

The disclosure concerns a resistive memory cell, including a stack of a selector, of a resistive element, and of a layer of phase-change material, the selector having no physical contact with the phase-change material. In one embodiment, the selector is an ovonic threshold switch formed on a conductive track of a metallization level.

A resistive memory device includes a bottom electrode, a top electrode and a resistance changing element. The top electrode is disposed above and spaced apart from the bottom electrode, and has a downward protrusion aligned with the bottom electrode. The resistance changing element covers side and bottom surfaces of the downward protrusion.