A method is provided that includes providing a memory device including a first word line, a vertical bit line, a non-volatile memory material disposed between the first word line and the vertical bit line, and a memory cell disposed between the first word line and the vertical bit line. The first word line has a first height. The method further includes forming one or more conductive filaments in the memory cell. The one or more conductive filaments are substantially confined to a filament region having a second height less than the first height and disposed substantially about a vertical center of the memory cell.

Stochastic or near-stochastic physical characteristics of resistive switching devices are utilized for generating data distinct to those resistive switching devices. The distinct data can be utilized for applications related to electronic identification. As one example, data generated from physical characteristics of resistive switching devices on a semiconductor chip can be utilized to form a distinct identifier sequence for that semiconductor chip, utilized for verification applications for communications with the semiconductor chip or utilized for generating cryptographic keys or the like for cryptographic applications.

Example subject matter disclosed herein relates to apparatuses and/or devices, and/or various methods for use therein, in which an application of an electric potential to a circuit may be initiated and subsequently changed in response to a determination that a snapback event has occurred in a circuit. For example, a circuit may comprise a memory cell that may experience a snapback event as a result of an applied electric potential. In certain example implementations, a sense circuit may be provided which is responsive to a snapback event occurring in a memory cell to generate a feed back signal to initiate a change in an electric potential applied to the memory cell.

A resistive random access memory device includes a first electrode; a solid metal oxide electrolyte; and a second electrode, the first and second electrodes being respectively arranged on either side of the solid metal oxide electrolyte, the second electrode being capable of supplying mobile ions circulating in the solid metal oxide electrolyte to the first electrode to form a conductive filament between the first and second electrodes when a potential difference is applied between the first and second electrodes. The device further includes an interface layer including a metal oxide, the interface layer extending at least partially onto the first electrode, the solid metal oxide electrolyte extending at least partially onto the interface layer.

Various embodiments comprise apparatuses having a number of memory cells including drive circuitry to provide signal pulses of a selected time duration and/or amplitude, and an array of resistance change memory cells electrically coupled to the drive circuitry. The resistance change memory cells may be programmed for a range of retention time periods and operating speeds based on the received signal pulse. Additional apparatuses and methods are described.

A non-volatile static random access memory has an operating mode, a data backup mode and a data restore mode. The non-volatile static random access memory includes a memory cell and a power saving module. The memory cell includes a latch, a set of latch switch units, a set of backup memory units, a set of backup activation units, a backup setting unit and a driving signal transmission unit. The power saving module includes a control switch unit, a backup determination unit and a restore switch unit. When backup data is different from data stored in the latch, a backup driving signal is generated by a node voltage of the backup memory units and outputted to a backup determination unit, which drives the backup setting unit to turn on according to the backup driving signal, so as to change the backup data in the backup memory units and ensure correct backup.

Various embodiments of the present disclosure are directed towards a memory device including a data storage structure overlying a substrate. A bottom electrode overlies the substrate and a top electrode overlies the bottom electrode. The data storage structure is disposed between the bottom electrode and the top electrode. The data storage structure comprises a dielectric material doped with a first dopant and a second dopant, where the first dopant is different from the second dopant.

The present disclosure relates to a storage device comprising a memory element. The memory element may comprise a changeable physical quantity for storing information. The physical quantity may be in a drifted state. The memory element may be configured for setting the physical quantity to an initial state. Furthermore, the memory element may comprise a drift of the physical quantity from the initial state to the drifted state. The initial state of the physical quantity may be computable by means of an initialization function. The initialization function may be dependent on a target state of the physical quantity and the target state of the physical quantity may be approximately equal to the drifted state of the physical quantity.

An arming switch structure and method of operation. The arming switch is integrated with a reactive material erasure device and phase change memory cell array and is coupled to a tamper detection device configured to trigger a signal for conduction to the reactive material erasure device that generates heat and induces a phase change in the phase change memory cell array. Prior to packaging, the memory chip is “armed” in a high-resistance state to prevent conduction of any signal to the reactive material erasure device. After the memory chip is packaged, the Reactive Material can be “disarmed” at a chosen time or condition by applying a bias to the arming switch activation layer, thereby heating and crystallizing the arming switch material, placing it in a low resistance state. In the disarmed state, the arming switch may conduct the trigger signal from tamper detection device to the reactive material erasure device.

A low voltage forming NVM structure including a plurality of ReRAM devices arranged in a cross bar array and sandwiched between a plurality of first electrically conductive structures and a plurality of second electrically conductive structures. Each first electrically conductive structure is oriented perpendicular to each second electrically conductive structure. The plurality of second electrically conductive structures includes a first set of second electrically conductive structures having a first top trench area A1, and a second set of second electrically conductive structures having a second top trench area A2 that is greater than A1. Each second electrically conductive structure of the first set contacts a surface of at least one of the first electrically conductive structures, and each second electrically conductive structure of the second set contacts a top electrode of at least one of the ReRAM devices.