A nonvolatile memory device according to an embodiment includes a substrate, a resistance change layer disposed over the substrate, a gate insulation layer disposed on the resistance change layer, a gate electrode layer disposed on the gate insulation layer, and a first electrode pattern layer and a second electrode pattern layer that are disposed respectively over the substrate and disposed to contact a different portion of the resistance change layer.

A semiconductor memory device has a first wiring extending in a first direction and a second wiring extending in a second direction. The first and second wirings are spaced from each other in a third direction. The second wiring has a first recess facing the first wiring. A resistance change memory element is connected between the first and second wirings. A conductive layer is between the resistance change memory element and the second wiring and includes a first protrusion facing the second wiring. A switching portion is between the conductive layer and the second wiring and includes a second recess facing the conductive layer and a second protrusion facing the second wiring. The first protrusion is in the second recess. The second protrusion is in the first recess. The switching portion is configured to switch conductivity state according to voltage between the first wiring and the second wiring.

An electronic device includes a base element, a source electrode layer and a drain electrode layer disposed to be spaced apart from each other on the base element, a channel layer disposed between the source electrode layer and the drain electrode layer on the base element that accommodates metal ions, a metal ion conduction layer disposed on the channel layer, and a gate electrode layer disposed on the metal ion conduction layer. The channel layer includes a plurality of unit films and channel spaces between the plurality of unit films. The plurality of unit films are arranged to be parallel to a direction substantially perpendicular to a surface of the base element.

A semiconductor device includes logic circuitry including a transistor disposed over a substrate, multiple layers each including metal wiring layers and an interlayer dielectric layer, respectively, disposed over the logic circuitry, and memory arrays. The multiple layers of metal wiring include, in order closer to the substrate, first, second, third and fourth layers, and the memory arrays include lower multiple layers disposed in the third layer.

Methods, systems, and devices for a decoding architecture for memory devices are described. Word line plates of a memory array may each include a sheet of conductive material that includes a first portion extending in a first direction within a plane along with multiple fingers extending in a second direction within the plane. Two word line plates in a same plane may be activated via a shared electrode. Memory cells coupled with the two word line plates sharing the electrode, or a subset thereof, may represent a logical page for accessing memory cells. A memory cell may be accessed via a first voltage applied to a word line plate coupled with the memory cell and a second voltage applied to a pillar electrode coupled with the memory cell. Parallel or simultaneous access operations may be performed for two or more memory cells within a same page of memory cells.

Methods, systems, and devices for decoding architecture for memory tiles are described. Word line tiles of a memory array may each include multiple word line plates, which may each include a sheet of conductive material that includes a first portion extending in a first direction within a plane along with multiple fingers extending in a second direction within the plane. A pillar tile may include one or more pillars that extend vertically between the word line plate fingers. Memory cells may each be couple with a respective word line plate finger and a respective pillar. Word line decoding circuitry, pillar decoding circuitry, or both, may be located beneath the memory array and in some cases may be shared between adjacent pillar tiles.

A semiconductor device includes a diffusion barrier structure, a bottom electrode, a top electrode over the bottom electrode, a switching layer and a capping layer. The bottom electrode is over the diffusion barrier structure. The top electrode is over the bottom electrode. The switching layer is between the bottom electrode and the top electrode, and configured to store data. The capping layer is between the top electrode and the switching layer. A thermal conductivity of the diffusion barrier structure is greater than approximately 20 W/mK.

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.

A resistance variable device of an embodiment includes a stack arranged between a first electrode and a second electrode and including a resistance variable layer and a chalcogen-containing layer. The chalcogen-containing layer contains a material having a composition represented by a general formula: C1.sub.xC2.sub.yA.sub.z, where C1 is at least one element selected from Sc, Y, Zr, and Hf, C2 is at least one element selected from C, Si, Ge, B, Al, Ga, and In, A is at least one element selected from S, Se, and Te, and x, y, and z are numbers representing atomic ratios satisfying 0<x<1, 0<y<1, 0<z<1, and x+y+z=1, and when an oxidation number of the element C1 is set to a, and an oxidation number of the element C2 is set to b, the atomic ratio x of the element C1 satisfies x≤(3−(3+b)×y−z)/(3+a).

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.