A memory cell including a memory element comprising an electrolytic insulator in contact with a conductive metal oxide (CMO) is disclosed. The CMO includes a crystalline structure and can comprise a pyrochlore oxide, a conductive binary oxide, a multiple B-site perovskite, and a Ruddlesden-Popper structure. The CMO includes mobile ions that can be transported to/from the electrolytic insulator in response to an electric field of appropriate magnitude and direction generated by a write voltage applied across the electrolytic insulator and CMO. The memory cell can include a non-ohmic device (NOD) that is electrically in series with the memory element. The memory cell can be positioned between a cross-point of conductive array lines in a two-terminal cross-point memory array in a single layer of memory or multiple vertically stacked layers of memory that are fabricated over a substrate that includes active circuitry for data operations on the array layer(s).

Row and/or column electrode lines for a memory device are staggered such that gaps are formed between terminated lines. Vertical interconnection to central points along adjacent lines that are not terminated are made in the gap, and vertical interconnection through can additionally be made through the gap without contacting the lines of that level.

An electronic device includes a substrate, a channel portion, a first electrode, a second electrode, and a shape change generation portion. The channel portion is provided above the substrate and includes a phase transition material that undergoes a phase transition between a metal phase and an insulator phase owing to shape change. The first electrode is provided above the channel portion and electrically connected to a part of an upper surface of the channel portion. The second electrode is provided above the channel portion and electrically connected to another part of the upper surface of the channel portion. The shape change generation portion is configured to force the channel portion to cause shape change.

A first electrode and an insulation material layer are sequentially formed over a substrate. A doping mask pattern is formed over the insulation material layer. The doping mask pattern exposes a portion of the insulation material layer. Dopants are injected into the exposed portion of the insulation material layer. The doping mask pattern is removed. A second electrode layer is formed over the insulation material layer. One or more pillar-shaped structures, each of which includes a second electrode, an insulation layer and a first electrode formed by respectively patterning the second electrode layer, the insulation material layer, and the first electrode layer. Each of the one or more pillar-shaped structures includes, in the insulation layer, a part of the exposed portion of the insulation material layer that is doped with the dopants. A threshold switching operation is performed in a region doped with the dopants of the insulation layer.

Described is an apparatus which comprises: a gate comprising a metal; a first layer adjacent to the gate, the first layer comprising a dielectric material; a second layer adjacent to the first layer, the second layer comprising a second material; a third layer adjacent to the second layer, the third layer comprising a third material including an amorphous metal oxide; a fourth layer adjacent to the third layer, the fourth layer comprising a fourth material, wherein the fourth and second materials are different than the third material; a source partially adjacent to the fourth layer; and a drain partially adjacent to the fourth layer.

A memory structure includes: first and second word lines; a high-k dielectric layer disposed on the first and second word lines; a channel layer disposed on the high-k dielectric layer and comprising a semiconductor material; first and second source electrodes electrically contacting the channel layer; a first drain electrode disposed on the channel layer between the first and second source electrodes; a memory cell electrically connected to the first drain electrode; and a bit line electrically connected to the memory cell.

A semiconductor memory cell including a capacitorless transistor having a floating body configured to store data as charge therein when power is applied to the cell, and a non-volatile memory comprising a bipolar resistive change element, and methods of operating.

Disclosed herein are electrolyte bismuth calcium ferrites having high oxygen vacancy ion mobility. There can be provided an oxygen vacancy electrolyte material including bismuth calcium ferrites (Bi.sub.1-xCa.sub.xFeO.sub.3-δ).

A switching element includes a lower barrier electrode disposed on a substrate, a switching pattern disposed on the lower barrier electrode, and an upper barrier electrode disposed on the switching pattern. The switching pattern includes a first switching pattern, and a second switching pattern disposed on the first switching pattern and having a density different from a density of the first switching pattern.

Provided is a memcapacitor. The memcapacitor includes: a first electrode having a metal-doped perovskite composition; a second electrode disposed on the first electrode; and a dielectric thin film having a perovskite composition, disposed between the first electrode and the second electrode, and having a variable dielectric constant depending on a voltage between the first electrode and the second electrode.