A two-terminal atom-based switching device having a fast operating speed and high durability and a manufacturing method thereof are disclosed. It is possible to reduce a forming voltage during positive voltage forming by forming an oxygen vacancy percolation path through negative voltage forming, which is first forming, and forming high binding energy and low formation energy between oxygen vacancies and metal ions implanted through positive voltage forming which is second forming after the negative voltage forming. Further, since a significant amount of metal ions implanted into the insulating layer through negative voltage application switching after the positive voltage forming is removed, the volatility of the two-terminal atom-based switching device may be improved, and a stuck-on failure phenomenon in the durability may be prevented.

Memory devices have an array of elements in two or more dimensions. The memory devices use multiple access lines arranged in a grid to access the memory devices. Memory cells are located at intersections of the access lines in the grid. Drivers are used for each access line and configured to transmit a corresponding signal to respective memory cells of the plurality of memory cells via a corresponding access line. The memory devices also include compensation circuitry configured to determine which driving access lines driving a target memory cell of the plurality of memory cells has the most distance between the target memory cell and a respective driver. The plurality of access lines comprise the driving access lines. The compensation circuitry also is configured to output compensation values to adjust the voltages of the driving access lines based on a polarity of the voltage of the longer driving access line.

Various aspects relate to a threshold switch structure and a use of such threshold switch structure as a threshold switch in a memory cell arrangement, the threshold switch structure including: a first electrode, a second electrode, a switch element in direct physical contact with the first electrode and the second electrode, the switch element including a layer of a spontaneously polarizable material. The first electrode, the second electrode, and the switch element are configured to allow for a switching of the switch element between a first electrical conductance state and a second electrical conductance state as a function of a voltage drop provided over the switch element by the first electrode and the second electrode.

Methods and apparatuses for thin film transistors and related fabrication techniques are described. The thin film transistors may access two or more decks of memory cells disposed in a cross-point architecture. The fabrication techniques may use one or more patterns of vias formed at a top layer of a composite stack, which may facilitate building the thin film transistors within the composite stack while using a reduced number of processing steps. Different configurations of the thin film transistors may be built using the fabrication techniques by utilizing different groups of the vias. Further, circuits and components of a memory device (e.g., decoder circuitry, interconnects between aspects of one or more memory arrays) may be constructed using the thin film transistors as described herein along with related via-based fabrication techniques.

In various embodiments. an electronic circuit is provided. The electronic circuit may include at least one memory cell and a control circuit configured to determine a formation state of the at least one memory cell and set a predefined function to a predefined state of executability (e.g., enabled or disabled) based on the determined formation states. For example, the predefined function may be set to the predefined state of executability only if the determined formation states of two or more memory cells match a predefined formation state pattern, or only if a minimum number or fraction of two or memory cells are in a predefined formation state. The formation state is either unformed or formed, wherein the unformed state is an electrically isolated state, and the formed state is a state into which an initially unformed memory cell is transformable and in which the formed memory cell is repeatedly switchable between a state of low electrical resistivity and a state of high electrical resistivity.

A memory device includes a bit line, a word line, a memory cell, select bit lines, and a controller. The memory cell includes a first transistor, data storage elements, and second transistors corresponding to the data storage elements. The first transistor includes a gate electrically coupled to the word line, a first source/drain, and a second source/drain. Each of the select bit lines is electrically coupled to a gate of a corresponding second transistor. Each data storage element and the corresponding second transistor are electrically coupled in series between the first source/drain of the first transistor and the bit line. The controller turns ON the first transistor and a selected second transistor, and, while the first transistor and the selected second transistor are turned ON, applies different voltages to the bit line to perform corresponding different operations on the data storage element coupled to the selected second transistor.

Disclosed is a resistive random access memory (RRAM). The RRAM includes a bottom electrode made of tungsten and a switching layer made of hafnium oxide disposed above the bottom electrode, wherein the switching layer includes a filament and one or more lateral regions including a doping material that are between a top region and a bottom region of the switching layer. The RRAM further includes a top electrode disposed above the switching layer.

The present disclosure generally relates to multi-switch storage cells (MSSCs), three-dimensional MSSC arrays, and three-dimensional MSSC memory. Multi-switch storage cells include a cell select device, multiple resistive change elements, and an intracell wiring electrically connecting the multiple resistive change elements together and to the cell select device. MSSC arrays are designed (architected) and operated to prevent inter-cell (sneak path) currents between multi-switch storage cells, which prevents stored data disturb from adjacent cells and adjacent cell data pattern sensitivity. Additionally, READ and WRITE operations may be performed on one of the multiple resistive change elements in a multi-switch storage cell without disturbing the stored data in the remaining resistive change elements. However, controlled parasitic currents may flow in the remaining resistive change elements within the cell. Isolating each multi-switch storage cell in a three-dimensional MSSC array, enables in-memory computing for applications such as data processing for machine learning and artificial intelligence.

A method for manufacturing a semiconductor memory device includes depositing a bottom metal line layer on a dielectric layer, and patterning the bottom metal line layer into a plurality of bottom metal lines spaced apart from each other. In the method, a plurality of switching element dielectric portions are formed on respective ones of the plurality of bottom metal lines, and a top metal line layer is deposited on the plurality of switching element dielectric portions. The method further includes patterning the top metal line layer into a plurality of top metal lines spaced apart from each other. The plurality of top metal lines are oriented perpendicular to the plurality of bottom metal lines.

In one embodiment, a method of performing an active polling operation can include: (i) detecting a self-timed operation that is to be executed on a serial memory device; (ii) determining if an active polling mode has been enabled; (iii) determining when the self-timed operation has completed execution on the serial memory device; and (iv) providing a completion indication external to the serial memory device when the self-timed operation has completed execution and the active polling mode is enabled.