Abstract: Methods, systems, and devices for a tapered cell profile and fabrication are described. A memory storage component may contain multiple chalcogenide materials and may include a tapered profile. For example, a first chalcogenide material may be coupled with a second chalcogenide material. Each of the chalcogenide materials may be further coupled with a conductive material (e.g., an electrode). Through an etching process, the chalcogenide materials may tapered (e.g., step tapered). A pulse may be applied to the tapered chalcogenide materials resulting in a memory storage component that includes a mixture of the chalcogenide materials.

Abstract: An electronic cell includes an integrated stack of structures including, successively: a first electrode; an ovonic threshold switch layer below the first electrode; and a fixed resistor below the ovonic threshold switch layer. A second electrode may be included between fixed resistor and the ovonic threshold switch layer. A memory layer, for example a phase change material layer, a resistive random-access memory layer or a magneto-resistive random-access memory layer, may be included between the first electrode and the ovonic threshold switch layer.

Abstract: The present disclosure includes memory cells having resistors, and methods of forming the same. An example method includes forming a first conductive line, forming a second conductive line, and forming a memory element between the first conductive line and the second conductive line. Forming the memory element can include forming one or more memory materials, and forming a resistor in series with the one or more memory materials. The resistor can be configured to reduce a capacitive discharge through the memory element during a state transition of the memory element.

Abstract: The present disclosure includes electrically formed memory arrays, and methods of processing the same. A number of embodiments include a plurality of conductive lines separated from one other by an insulation material, a first plurality of conductive extensions arranged to extend substantially perpendicular to the plurality of conductive lines, a storage element material formed around each respective one of the first plurality of conductive extensions, a second plurality of conductive extensions arranged to extend substantially perpendicular to the plurality of conductive lines, and a plurality of single element materials formed around each respective one of the second plurality of conductive extensions.

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 access line formation for a memory array are described. The techniques described herein may be used to fabricate access lines for one or more decks of a memory array. In some examples, one or more access lines of a deck may be formed using an independent processing step. For example, different fabrication processes may be used to form a plurality of access lines in a deck and to form the pillars (e.g., the memory cells) that are coupled with the access lines. In some examples, an offset between the access lines and the pillars may exist due to the components being fabricated in different processing steps.

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: A method of forming an array of memory cells, where the array comprises an elevationally-inner tier of memory cells comprising spaced-inner-tier-lower-first-conductive lines and inner-tier-programmable material directly there-above, an elevationally-outer tier of memory cells comprising spaced-outer-tier-lower-first-conductive lines and outer-tier-programmable material directly there-above, and spaced-upper-second-conductive lines that are electrically shared by the outer-tier memory cells and the inner-tier memory cells, comprises depositing conductor material for all of the shared-spaced-upper-second-conductive lines. All of the conductor material for all of the shared-spaced-upper-second-conductive lines is patterned using only a single masking step. Other method embodiments and arrays of memory cells independent of method of manufacture are disclosed.

Abstract: Methods, systems, and devices for access line formation for a memory array are described. The techniques described herein may be used to fabricate access lines for one or more decks of a memory array. In some examples, one or more access lines of a deck may be formed using an independent processing step. For example, different fabrication processes may be used to form a plurality of access lines in a deck and to form the pillars (e.g., the memory cells) that are coupled with the access lines. In some examples, an offset between the access lines and the pillars may exist due to the components being fabricated in different processing steps.

Abstract: One embodiment provides a method of making a memory device. The method includes forming a via in a bit line, an interlayer and a dielectric region. The bit line is formed on the interlayer. The interlayer is formed partially on the dielectric region and partially on a plurality of memory cells. The via has a first end included in, and in direct contact with, the bit line and a second end to couple to an electrical contact.

Abstract: Various embodiments of a three-dimensional cross-point (3D X-point) memory cell design include one or more electrodes having an increased resistance compared to existing memory cell designs or compared to other electrodes within a same memory cell. A memory device includes an array of memory cells with each memory cell arranged between a word line and a bit line of the memory device. Some embodiments include additional material layers to increase memory cell resistance. Some embodiments include electrodes having an increased thickness to increase the resistance. Some embodiments include electrodes having a composition with a higher resistivity. Some embodiments include electrodes with increased interface resistance. Some embodiments include a combination of such features. In any case, the resulting increased memory cell resistance causes a reduction in the transient selection current for the given memory cell.

Abstract: The present disclosure includes textured memory cell structures and method of forming the same. In one or more embodiments, a memory cell includes a buffer portion formed on an amorphous portion and an active portion formed on the buffer portion, wherein the active portion is textured with a single out of plane orientation.

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: Some embodiments include a fuse having a tungsten-containing structure directly contacting an electrically conductive structure. The electrically conductive structure may be a titanium-containing structure. An interface between the tungsten-containing structure and the electrically conductive structure is configured to rupture when current through the interface exceeds a predetermined level. Some embodiments include a method of forming and using a fuse. The fuse is formed to have a tungsten-containing structure directly contacting an electrically conductive structure. An interface between the tungsten-containing structure and the electrically conductive structure is configured to rupture when current through the interface exceeds a predetermined level. Current exceeding the predetermined level is passed through the interface to rupture the interface.

Abstract: Methods, systems, and devices for drift mitigation with embedded refresh are described. A memory cell may be written to and read from using write and read voltages, respectively, that are of different polarities. For example, a memory cell may be written to by applying a first write voltage and may be subsequently read from by applying a first read voltage of a first polarity. At least one additional (e.g., a second) read voltage—a setback voltage—of a second polarity may be utilized to return the memory cell to its original state. Thus the setback voltage may mitigate a shift in the voltage distribution of the cell caused by the first read voltage.

Abstract: Memory devices for embedded applications are described. A memory device may include an array of memory cells having a first area and configured to operate at a first voltage, and circuitry having a second area that at least partially overlaps the first area. The circuitry may be configured to operate at a second voltage lower than the first voltage. The circuitry maybe be further configured to access the array of memory cells using decoder circuitry configured to operate at the first voltage. The array of memory cells and the circuitry may be on a single substrate. The circuitry may include microcontroller circuitry, cryptographic controller circuitry, and/or memory controller circuitry. The memory cells may be self-selecting memory cells that each include a storage and selector element having a chalcogenide material. The memory cells may not include separate cell selector circuitry.

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: 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 a decoder are described. The memory device may include a substrate, an array of memory cells coupled with the substrate, and a decoder coupled with the substrate. The decoder may include a doped material that may extend between a first conductive line and an access line of the array of memory cells in a first direction (e.g., away from a surface of the substrate) and the doped material may be configured to selectively couple the first conductive line of the decoder with the access line of the array of memory cells. The access line may be coupled with two decoders, in some cases.