A material belonging to the family of centrosymmetric Mott insulators is used as an active material in a resistively switched memory for storing data. The material is placed between two electrical electrodes, by virtue of which an electric field of a preset value is applied in order to form, by way of an electron avalanche effect, an elementary information cell that has at least two logic states.

A memory cell includes: a first contact feature partially embedded in a first dielectric layer; a barrier layer, lining the first contact feature, that comprises a first portion disposed between the first contact feature and first dielectric layer, and a second portion disposed above the first dielectric layer; a resistive material layer disposed above the first contact feature, the resistive material layer coupled to the first contact feature through the second portion of the barrier layer; and a second contact feature embedded in a second dielectric layer above the first dielectric layer.

Techniques for controlling the programming current of a PCM-based AI device using an external resistor are provided. In one aspect, a PCM cell includes: a PCM stack, that has a bottom electrode; a heater disposed directly on the bottom electrode; a PCM unit including a first material disposed on the heater; a top electrode including a second material disposed on the PCM unit; and a resistor adjacent to the PCM stack, wherein the resistor includes a combination of the first material and the second material. A PCM device that includes at least one of the PCM cells, and a method of forming the PCM cell are also provided.

A memory cell with a recessed bottom electrode and methods of forming the memory cell are described. A bottom electrode can be deposited on a layer of a structure. A first insulator and a second insulator can be deposited on top of the bottom electrode. The first insulator and the second insulator can be spaced apart from one another to form an opening on top of the bottom electrode. A recess can be etched in the bottom electrode. The recess can be etched in a portion of the bottom electrode that is underneath the opening. The recess and the opening can form a pore. Phase change material can be deposited in the pore to form a memory cell.

A phase change memory (PCM) device is provided. The PCM device includes a bottom electrode formed on a substrate, a heater electrode formed on the bottom electrode, the heater electrode having a tapered portion that becomes narrower in a direction away from the substrate. The PCM device also includes an interlayer dielectric (ILD) layer formed on the tapered portion of the heater electrode, the interlayer layer dielectric including an airgap that at least partially surrounds the tapered portion of the heater electrode. The PCM device also includes a phase change layer formed on the heater electrode, and a top electrode formed on the phase change layer.

The disclosure belongs to the technical field of microelectronic devices and memories, and discloses a three-dimensional stacked phase change memory and a preparation method thereof. The preparation method includes: preparing a multilayer structure in which horizontal electrode layers and insulating layers are alternately stacked, then performing etching to form trenches and separated three-dimensional strip electrodes, next filling the trenches with an insulating medium, and then forming small holes at the boundary region between the three-dimensional strip electrodes and the insulating medium, thereafter sequentially depositing a phase change material on the walls of the small holes, and filling the small holes with an electrode material to prepare vertical electrodes, so as to obtain a three-dimensional stacked phase change memory stacked in multiple layers. By improving the overall process of the preparation method, the disclosure realizes the establishment of a three-dimensional phase change memory array by using a vertical electrode structure.

A semiconductor device includes a bottom electrode, a top electrode over the bottom electrode, a switching layer between the bottom electrode and the top electrode, wherein the switching layer is configured to store data, a capping layer in contact with the switching layer, wherein the capping layer is configured to extract active metal ions from the switching layer, an ion reservoir region formed in the capping layer, a diffusion barrier layer between the bottom electrode and the switching layer, wherein the diffusion barrier layer includes palladium (Pd), cobalt (Co), or a combination thereof and is configured to obstruct diffusion of the active metal ions between the switching layer and the bottom electrode, and the diffusion layer has a concaved top surface, and a passivation layer covering a portion of the top electrode, and wherein the passivation layer directly contacts a top surface of the switching layer.

A semiconductor device includes a PCM stack that includes bottom electrode liner over a lower heater. The bottom electrode liner has a top-down view plus (+) geometry with a ‘horizontal’ portion being orthogonal to a ‘vertical’ portion. An airgap is formed within the PCM stack in an area located adjacent and between the ‘horizontal’ portion and the ‘vertical’ portion. The airgap has a substantially smaller dielectric constant than the surrounding PCM stack material(s). Therefore, the airgap may effectively reduce the amount of current that leaks from the PCM stack when flowing from the bottom electrode liner to a top contact or top electrode. Further, the airgap may allow for expansion of the surrounding PCM stack material(s) that may result from the heating of the PCM stack.

A front-end method of fabricating nickel plated caps over copper bond pads used in a memory device. The method provides protection of the bond pads from an oxidizing atmosphere without exposing sensitive structures in the memory device to the copper during fabrication.

The present disclosure discloses a self-gated RRAM cell and a manufacturing method thereof; which belong to the field of microelectronic technology. The self-gated RRAM cell comprises: a stacked structure containing multiple layers of conductive lower electrodes; a vertical trench formed by etching the stacked structure; a M.sub.8XY.sub.6 gated layer formed on an inner wall and a bottom of the vertical trench; a resistance transition layer formed on a surface of the M.sub.8XY.sub.6, gated layer; and a conductive upper electrode formed on a surface of the resistance transition layer, the vertical trench being filled with the conductive upper electrode. The present disclosure is implemented on a basis of using the self-gated RRAM as a memory cell. It may not depend on a gated transistor and a diode, but relies on a non-linear variation characteristic of resistance of its own varied with voltage to achieve a self-gated function, which has a simple structure, easy integration, high density and low cost, capable of suppressing a reading crosstalk phenomenon in a cross array structure; and is also adapted for a planar stacked cross array structure and a vertical cross array structure, achieving 3D storage with a high density.