Abstract: Methods, systems, and devices for programming enhancement in memory cells are described. An asymmetrically shaped memory cell may enhance ion crowding at or near a particular electrode, which may be leveraged for accurately reading a stored value of the memory cell. Programming the memory cell may cause elements within the cell to separate, resulting in ion migration towards a particular electrode. The migration may depend on the polarity of the cell and may create a high resistivity region and low resistivity region within the cell. The memory cell may be sensed by applying a voltage across the cell. The resulting current may then encounter the high resistivity region and low resistivity region, and the orientation of the regions may be representative of a first or a second logic state of the cell.

Abstract: Methods, systems, and devices for operating memory cell(s) are described. A resistance of a storage element included in a memory cell may be programmed by applying a voltage to the memory cell that causes ion movement within the storage element, where the storage element remains in a single phase and has different resistivity based on a location of the ions within the storage element. In some cases, multiple of such storage elements may be included in a memory cell, where ions within the storage elements respond differently to electric pulses, and a non-binary logic value may be stored in the memory cell by applying a series of voltages or currents to the memory cell.

Abstract: Methods, systems, and devices for adaptive write operations for a memory device are described. In an example, the described techniques may include identifying a quantity of access operations performed on a memory array, modifying one or more parameters for a write operation based on the identified quantity of access operations, and writing logic states to the memory array by performing the write operation according to the one or more modified parameters. In some examples, the memory array may include memory cells associated with a configurable material element, such as a chalcogenide material, that stores a logic state based on a material property of the material element. In some examples, the described techniques may at least partially compensate for a change in memory material properties due to aging or other degradation or changes over time (e.g., due to accumulated access operations).

Abstract: A multi-layer memory device with an array having multiple memory decks of self-selecting memory cells is provided in which N memory decks may be fabricated with N+1 mask operations. The multiple memory decks may be self-aligned and certain manufacturing operations may be performed for multiple memory decks at the same time. For example, patterning a bit line direction of a first memory deck and a word line direction in a second memory deck above the first memory deck may be performed in a single masking operation, and both decks may be etched in a same subsequent etching operation. Such techniques may provide efficient fabrication which may allow for enhanced throughput, additional capacity, and higher yield for fabrication facilities relative to processing techniques in which each memory deck is processed using two or more mask and etch operations per memory deck.

Abstract: Methods, systems, and devices related to techniques to access a self-selecting memory device are described. A self-selecting memory cell may store one or more bits of data represented by different threshold voltages of the self-selecting memory cell. A programming pulse may be varied to establish the different threshold voltages by modifying one or more time durations during which a fixed level of voltage or current is maintained across the self-selecting memory cell. The self-selecting memory cell may include a chalcogenide alloy. A non-uniform distribution of an element in the chalcogenide alloy may determine a particular threshold voltage of the self-selecting memory cell. The shape of the programming pulse may be configured to modify a distribution of the element in the chalcogenide alloy based on a desired logic state of the self-selecting memory cell.

Abstract: Methods, systems, and devices for read refresh operations are described. A memory device may include a plurality of sub-blocks of memory cells. Each sub-block may undergo a quantity of access operations (e.g., read operations, write operations). Based on the quantity of access operations performed on any one sub-block over a period of time, a read refresh operation may be performed on the memory cells of the sub-block. A read refresh operation may refresh and/or restore the data stored to the memory cells of the sub-block, and be initiated based on the memory device receiving an operation code (e.g., from a host device).

Abstract: Methods, systems, and devices for read refresh operations are described. A memory device may include a plurality of sub-blocks of memory cells. Each sub-block may undergo a quantity of access operations (e.g., read operations, write operations). Based on the quantity of access operations performed on any one sub-block over a period of time, a read refresh operation may be performed on the memory cells of the sub-block. A read refresh operation may refresh and/or restore the data stored to the memory cells of the sub-block, and be initiated based on the memory device receiving an operation code (e.g., from a host device).

Abstract: Methods, systems, and devices for multi-deck memory arrays are described. A multi-deck memory device may include a memory array with a cell having a self-selecting memory element and another array with a cell having a memory storage element and a selector device. The device may be programmed to store multiple combinations of logic states using cells of one or more decks. Both the first deck and second deck may be coupled to at least two access lines and may have one access line that is a common access line, coupling the two decks. Additionally, both decks may overlie control circuitry, which facilitates read and write operations. The control circuitry may be configured to write a first state or a second state to one or both of the memory decks via the access lines.

Abstract: The disclosed technology generally relates to integrated circuit devices, and in particular to cross-point memory arrays and methods for fabricating the same. Line stacks are formed, including a storage material line disposed over lower a conductive line. Upper conductive lines are formed over and crossing the line stacks, exposing portions of the line stacks between adjacent upper conductive lines. After forming the upper conductive lines, storage elements are formed at intersections between the lower conductive lines and the upper conductive lines by removing storage materials from exposed portions of the line stacks, such that each storage element is laterally surrounded by spaces. A continuous sealing material laterally surrounds each of the storage elements.

Abstract: In an example, a first data structure can be read with a first read voltage dedicated to the first data structure. A second data structure that stores a larger quantity of data than the first data structure can be with a second read voltage that is dedicated to the second data structure. The first data structure can be with a third read voltage in response to a quantity of errors in reading the first data structure being greater than or equal to a first threshold quantity. The second data structure can be read with the third read voltage in response to a quantity of errors in reading the second data structure being greater than or equal to a second threshold quantity. The read voltages can be based on a temperature of an apparatus that includes the first and second data structures.

Abstract: Methods, systems, devices, and other implementations to store fuse data in memory devices are described. Some implementations may include an array of memory cells with different portions of cells for storing data. A first portion of the array may store fuse data and may contain a chalcogenide storage element, while a second portion of the array may store user data. Sense circuitry may be coupled with the array, and may determine the value of the fuse data using various signaling techniques. In some cases, the sense circuitry may implement differential storage and differential signaling to determine the value of the fuse data stored in the first portion of the array.

Abstract: Embodiments disclosed herein may include depositing a storage component material over and/or in a trench in a dielectric material, including depositing the storage component material on approximately vertical walls of the trench and a bottom of the trench. Embodiments may also include etching the storage component material so that at least a portion of the storage component material remains on the approximately vertical walls and the bottom of the trench, wherein the trench is contacting an electrode and a selector such that storage component material on the bottom of the trench contacts the electrode.

Abstract: Methods, systems, and devices for varying-polarity read operations for polarity-written memory cells are described. Memory cells may be programmed to store different logic values based on applying write voltages of different polarities to the memory cells. A memory device may read the logic values based on applying read voltages to the memory cells, and the polarity of the read voltages may vary such that at least some read voltages have one polarity and at least some read voltages have another polarity. The read voltage polarity may vary randomly or according to a pattern and may be controlled by the memory device or by a host device for the memory device.

Abstract: Methods, systems, and devices related to a multi-level self-selecting memory device are described. A self-selecting memory cell may store one or more bits of data represented by different threshold voltages of the self-selecting memory cell. A programming pulse may be varied to establish the different threshold voltages by modifying one or more durations during which a fixed level of voltage or fixed level of current is maintained across the self-selecting memory cell. The self-selecting memory cell may include a chalcogenide alloy. A non-uniform distribution of an element in the chalcogenide alloy may determine a particular threshold voltage of the self-selecting memory cell. The shape of the programming pulse may be configured to modify a distribution of the element in the chalcogenide alloy based on a desired logic state of the self-selecting memory cell.

Abstract: Disclosed technology relates generally to integrated circuits, and more particularly, to structures incorporating and methods of forming metal lines including tungsten and carbon, such as conductive lines for memory arrays. In one aspect, a memory device comprises a lower conductive line extending in a first direction and an upper conductive line extending in a second direction and crossing the lower conductive line, wherein at least one of the upper and lower conductive lines comprises tungsten and carbon. The memory device additionally comprises a memory cell stack interposed at an intersection between the upper and lower conductive lines. The memory cell stack includes a first active element over the lower conductive line and a second active element over the first active element, wherein one of the first and second active elements comprises a storage element and the other of the first and second active elements comprises a selector element.

Abstract: Methods, systems, and devices for multi-component cell architectures for a memory device are described. A memory device may include self-selecting memory cells that include multiple self-selecting memory components (e.g., multiple layers or other segments of a self-selecting memory material, separated by electrodes). The multiple self-selecting memory components may be configured to collectively store one logic state based on the polarity of a programming pulse applied to the memory cell. The multiple memory component layers may be collectively (concurrently) programmed and read. The multiple self-selecting memory components may increase the size of a read window of the memory cell when compared to a memory cell with a single self-selecting memory component. The read window for the memory cell may correspond to the sum of the read windows of each self-selecting memory component.

Abstract: Disclosed herein is a memory cell. The memory cell may act both as a combined selector device and memory element. The memory cell may be programmed by applying write pulses having different polarities. Different polarities of the write pulses may program different logic states into the memory cell. The memory cell may be read by read pulses all having the same polarity. The logic state of the memory cell may be detected by observing different threshold voltages when the read pulses are applied. The different threshold voltages may be responsive to the different polarities of the write pulses.

Abstract: Methods, systems, and devices for mimicking neuro-biological architectures that may be present in a nervous system are described herein. A memory device may include a memory unit configured to store a value. A memory unit may include a first memory cell (e.g., an aggressor memory cell) and a plurality of other memory cells (e.g., victim memory cells). The memory unit may use thermal disturbances of the victim memory cells that may be based on an access operation to store the analog value. Thermal energy output by the aggressor memory cell during an access operation (e.g., a write operation) may cause the state of the victim memory cells to alter based on thermal relationship between the aggressor memory cell and at least some of the victim memory cells. The memory unit may be read by detecting and combining the weights of the victim memory cells during a read operation.

Abstract: In an example, a memory array may include a plurality of first dielectric materials and a plurality of stacks, where each respective first dielectric material and each respective stack alternate, and where each respective stack comprises a first conductive material and a storage material. A second conductive material may pass through the plurality of first dielectric materials and the plurality of stacks. Each respective stack may further include a second dielectric material between the first conductive material and the second conductive material.

Abstract: Methods, systems, devices, and other implementations to store fuse data in memory devices are described. Some implementations may include an array of memory cells with different portions of cells for storing data. A first portion of the array may store fuse data and may contain a chalcogenide storage element, while a second portion of the array may store user data. Sense circuitry may be coupled with the array, and may determine the value of the fuse data using various signaling techniques. In some cases, the sense circuitry may implement differential storage and differential signaling to determine the value of the fuse data stored in the first portion of the array.