A system may include an array of interconnected memristors. Each memristor may include a first electrode, a second electrode, and a memristor material positioned between the first electrode and the second electrode. The system may further include a controller communicatively coupled to the array of interconnected memristors. The controller may be configured to tune the array of interconnected memristors.

The present disclosure discloses a method for manufacturing a resistive switching element, including: performing an etching process, a deposition process and a polishing process alternately to prepare the bottom electrode, the resistive switching layer and the top electrode; and optimizing at least one of the bottom electrode, the resistive switching materials and the oxygen storage layer by using the sidewall process when preparing the bottom electrode and the resistive switching materials, so as to reduce a contact area between the bottom electrode and the resistive switching materials, and/or reduce a contact area between the resistive switching materials and the oxygen storage layer. The method could form conductive filaments in the resistive switching layer, and a low resistive state and high resistive state are realized by forming and breaking conductive filaments. The present disclosure further discloses a resistive switching element and a resistive switching memory having the resistive switching element.

A method may include forming a bottom electrode in an interlayer dielectric, depositing a liner on top of the bottom electrode, depositing a phase change material layer on top of the liner, wherein a top surface of the liner is in direct contact with a bottom surface of the phase change material layer, and depositing a barrier on top of the phase change material layer, wherein a top surface of the phase change material layer is in direct contact with a bottom surface of the barrier. The barrier may be made of doped phase change material. The forming of the bottom electrode may further include forming a via in the interlayer dielectric, depositing an outer layer along a bottom and a sidewall of the via, depositing a middle layer on top of the outer layer, and depositing an inner layer on top of the middle layer.

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.

Electrical switching technologies employ the otherwise undesirable line defect in crystalline materials to form conductive filaments. A switching cell includes a crystalline layer disposed between an active electrode and another electrode. The crystalline layer has at least one channel, such as a line defect, extending from one surface of the crystalline layer to the other surface. Upon application of a voltage on the two electrodes, the active electrode provides metal ions that can migrate from the active electrode to the other electrode along the line defect, thereby forming a conductive filament. The switching cell can precisely locate the conductive filament within the line defect and increase the device-to-device switching uniformity.

A nonvolatile memory device group includes: (A) a first insulating layer; (B) a second insulating layer that has a first concavity and a second concavity communicating with the first concavity and having a width larger than that of the first concavity and that is disposed on the first insulating layer; (C) a plurality of electrodes that are disposed in the first insulating layer and the top surface of which is exposed from the bottom surface of the first concavity; (D) an information storage layer that is formed on the side walls and the bottom surfaces of the first concavity and the second concavity; and (E) a conductive material layer that is filled in a space surrounded with the information storage layer in the second concavity.

A memory structure includes a first dielectric layer, having a first top surface, over a conductive structure. A first opening in the first dielectric layer exposes an area of the conductive structure, and has an interior sidewall. A first electrode structure, having a first portion and a second portion, is over the exposed area of the conductive structure. The second portion extends upwardly along the interior sidewall. A resistance variable layer is disposed over the first electrode. A second electrode structure, having a third portion and a fourth portion, is over the resistance variable layer. The third portion has a second top surface below the first top surface of the first dielectric layer. The fourth portion extends upwardly along the resistance variable layer. A second opening is defined by the second electrode structure. At least a part of a second dielectric layer is disposed in the second opening.

The forming voltage of a resistance change element used in a non-volatile memory and the like is decreased, and repetition characteristics are improved. In an element structure in which a metal oxide film 12 is sandwiched between a lower electrode 11 and an upper electrode 14, an island/particle-like region of amorphous aluminum oxide or aluminum oxycarbide 13 is formed on the metal oxide film 12. Because an oxide deficiency, serving as the nucleus of a filament for implementing an on/off operation of the resistance change element, is formed from the beginning under the island- or particle-like aluminum oxide or the like, the conventional creation of an oxide deficiency by high-voltage application in the initial period of forming can be eliminated. Such a region can be fabricated using a small number of cycles of an ALD process.

A memory using mixed valence conductive oxides is disclosed. The memory includes a mixed valence conductive oxide that is less conductive in its oxygen deficient state and a mixed electronic ionic conductor that is an electrolyte to oxygen and promotes an electric field effective to cause oxygen ionic motion.

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.