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: Subject matter described pertains to methods, apparatuses, and circuits for programming a memory device.

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 be configured to apply a voltage to an access line of the array of memory cells as part of an access operation. The decoder may include a first conductive line configured to carry the voltage applied to the access line of the array of memory cells. In some cases, the decoder may include a doped material extending between the first conductive line and the 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.

Abstract: An example three-dimensional (3-D) memory array includes a first plurality of conductive lines separated from one other by an insulation material, a second plurality of conductive lines, and a plurality of pairs of conductive pillars arranged to extend substantially perpendicular to the first plurality of conductive lines and the second plurality of conductive lines. The conductive pillars of each respective pair are coupled to a same conductive line of the second plurality of conductive lines. A storage element material is formed partially around the conductive pillars of each respective pair.

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 nonvolatile memory device includes a metal silicon nitride layer on a three-dimensional (3D) crosspoint architecture, where the metal silicon nitride layer is in the memory array processing. The metal silicon nitride layer is patterned in accordance with the memory array structure, rather than being an underlying layer for a metal layer. The metal layer provides bitline or wordline select paths, and can connect to a via in parallel with the memory array stack. The metal silicon nitride layer is between the metal layer and the memory array, and is not present over the via.

Abstract: 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: Phase change memory apparatuses include memory cells including phase change material, bit lines electrically coupled to aligned groups of at least some of the memory cells, and heating elements electrically coupled to the phase change material of the memory cells. The heating elements include vertical portions extending in a bit line direction. Additional phase change memory apparatuses include dummy columns positioned between memory columns and base contact columns. The dummy columns include phase change memory cells and lack heating elements coupled to the phase change memory cells thereof. Additional phase change memory apparatuses include heating elements operably coupled to phase change memory cells. An interfacial area between the heating elements and the phase change memory cells has a length that is independent of a bit line width. Methods relate to forming such phase change memory apparatuses.

Abstract: A thermally optimized phase change memory cell includes a phase change material element disposed between first and second electrodes. The second electrode includes a thermally insulating region having a first thermal resistivity over the first electrode and a metallic contact region interposed between the phase change material element and the thermally insulating region, where the metallic contact layer has a second thermal resistivity lower than the first thermal resistivity.

Abstract: 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 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: A memory structure can include a memory cell, a via, a dielectric material separating the memory cell from the via, a metal ceramic composite material layer on the memory cell and the dielectric material, and a conductive layer on the metal ceramic composite material layer and the via. The conductive layer can be in direct contact with the top surface of the via.

Abstract: Disclosed herein is a memory cell including a memory element and a selector device. The memory cell may be programmed with a programming pulse having a first polarity and read with a read pulse having a second polarity. The memory cell may be programmed with a programming pulse having first and second portions. The first and second portions may have different magnitudes and polarities. The memory cell may exhibit reduced voltage drift and/or threshold voltage distribution. Described herein is a memory cell that acts as both a memory element and a selector device. The memory cell may be programmed with a programming pulse having first and second portions. The first and second portions may have different magnitudes and polarities.

Abstract: An example three-dimensional (3-D) memory array includes a first plurality of conductive lines separated from one other by an insulation material, a second plurality of conductive lines, and a plurality of pairs of conductive pillars arranged to extend substantially perpendicular to the first plurality of conductive lines and the second plurality of conductive lines. The conductive pillars of each respective pair are coupled to a same conductive line of the second plurality of conductive lines. A storage element material is formed partially around the conductive pillars of each respective pair.

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 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 be configured to apply a voltage to an access line of the array of memory cells as part of an access operation. The decoder may include a first conductive line configured to carry the voltage applied to the access line of the array of memory cells. In some cases, the decoder may include a doped material extending between the first conductive line and the 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.

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: Embodiments disclosed herein relate to operating a memory cell as an anti-fuse, such as for use in phase change memory, for example.

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.