Some embodiments include an arrangement having a memory tier with memory cells on opposing sides of a coupling region. First sense/access lines are under the memory cells, and are electrically connected with the memory cells. A conductive interconnect is within the coupling region. A second sense/access line extends across the memory cells, and across the conductive interconnect. The second sense/access line has a first region having a second conductive material over a first conductive material, and has a second region having only the second conductive material. The first region is over the memory cells, and is electrically connected with the memory cells. The second region is over the conductive interconnect and is electrically coupled with the conductive interconnect. An additional tier is under the memory tier, and includes CMOS circuitry coupled with the conductive interconnect. Some embodiments include methods of forming multitier arrangements.

A semiconductor memory includes a substrate including a first region in which a plurality of variable resistance elements are arranged, second and third regions on different sides of the first region, a plurality of first lines disposed over the substrate and extending across the first region and the second region, a plurality of second lines disposed over the first lines and extending across the first region and the third region. The variable resistance elements are positioned at intersections of the first lines and the second lines between the first lines and the second lines, a contact plug is disposed in the third region with an upper end coupled to the second line, and a resistive material layer is interposed between the second line and the variable resistance element in the first region but not between the second line and the contact plug in the third region.

A method for manufacturing a semiconductor device includes forming a first pattern structure having a first opening on a lower structure comprising a semiconductor substrate. The first pattern structure includes a stacked pattern and a first spacer layer covering at least a side surface of the stacked pattern. A first flowable material layer including a SiOCH material is formed on the first spacer layer to fill the first opening and cover an upper portion of the first pattern structure. A first curing process including supplying a gaseous ammonia catalyst into the first flowable material layer is performed on the first flowable material layer to form a first cured material layer that includes water. A second curing process is performed on the first cured material layer to form a first low-k dielectric material layer. The first low-k dielectric material layer is planarized to form a planarized first low-k dielectric material layer.

A memory device may be provided, including a substrate; one or more bottom electrodes arranged over the substrate; one or more switching layers arranged over the one or more bottom electrodes; and a plurality of top electrodes arranged over the one or more switching layers. Each of the one or more bottom electrodes may include at least one corner tip facing the switching layer, and an angle of each of the at least one corner tip may be less than ninety degrees.

The present disclosure includes apparatuses and methods for material implication operations in memory with reduced program voltages. An example apparatus can include an array of memory cells that further includes a first memory cell coupled to a first access line and to a first one of a plurality of second access lines and a second memory cell coupled to the first access line and to a second one of the plurality of second access lines. The circuitry can be configured to apply, across the second memory cell, a first voltage differential having a first polarity and a first magnitude. The first voltage differential reduces, if the second memory cell is programmed to a first data state, a magnitude of a drifted threshold voltage for programming the second memory cell to a second data state. The circuitry is further configured to apply, subsequent to the application of the first voltage differential, a first signal to the first access line. The circuitry is further configured to, while the first signal is being applied to the first access line, apply, subsequent to the application of the first voltage differential, a second voltage differential having a second polarity and the first magnitude across the first memory cell and apply a third voltage differential having the second polarity across the second memory cell. A material implication operation is performed as a result of the first, second, and third voltage differentials applied across the first and the second memory cells with a result of the material implication operation being stored on the second memory cell.

An resistive random-access memory (RRAM) device including an first crystalline semiconductor layer disposed adjacent to a crystalline semiconductor substrate, a crystal lattice edge-dislocation segment disposed at an interface of the first crystalline semiconductor layer and crystalline semiconductor substrate, the lattice edge-dislocation segment including first and second segment ends, a first ion-source electrode disposed upon the electrically isolating spacer, adjacent to the crystalline substrate and first crystalline semiconductor layer, and further disposed in contact with the first segment end of the lattice edge-dislocation segment, and a second electrode disposed upon the electrically isolating spacer, adjacent to the crystalline substrate and first crystalline semiconductor layer, and further disposed in contact with the second segment end of the lattice edge-dislocation segment.

A selector includes a first electrode, a second electrode, and a selector layer provided between the first electrode and the second electrode and contains Si.sub.xTe.sub.yN.sub.z. The x, y, and z of the Si.sub.xTe.sub.yN.sub.z satisfy 0<x≤35, 15≤y≤50, and 50<z≤85, satisfy 0<x≤45, 15≤y≤55, and 40<z≤85, or satisfy 0<x≤55, 15≤y≤65, and 30<z≤85.

A memory device includes a transistor, a memory cell, and an interconnect layer. The transistor includes a bottom source/drain portion, a channel portion, and a top source/drain portion stacked from bottom to top and a gate structure surrounding the channel portion. The memory cell includes a nanowire bottom electrode, a first dielectric layer, a second dielectric layer, and a top electrode. The first dielectric layer laterally surrounds the nanowire bottom electrode. The second dielectric layer is over the nanowire bottom electrode and the first dielectric layer. The second dielectric layer is in contact with a top surface of the nanowire bottom electrode and a sidewall of the first dielectric layer. The top electrode covers the second dielectric layer. The interconnect layer is over the transistor and the memory cell to interconnect the transistor and the memory cell.

A hybrid switch and memory cell includes a transistor device that has an atomically-thin semiconductor material channel, source/drain electrodes, and gate dielectric. The cell includes a resistive-random-access-memory having a thin conductive edge and a 2D insulator layer over the thin conductive edge, wherein the 2D insulator layer extends over the semiconductor channel and serves as the gate dielectric in the transistor device.

A high bandwidth memory is provided. The high bandwidth memory includes a region of dynamic random access memory devices, a region of non-volatile memory devices adjacent to the region of dynamic random access memory devices, and a region of logic devices adjacent to both the region of dynamic random access memory devices and the region of non-volatile memory devices.