Semiconductor devices and structures, such as phase change memory devices, include peripheral conductive pads coupled to peripheral conductive contacts in a peripheral region. An array region may include memory cells coupled to conductive lines. Methods of forming such semiconductor devices and structures include removing memory cell material from a peripheral region and, thereafter, selectively removing portions of the memory cell material from the array region to define individual memory cells in the array region. Additional methods include planarizing the structure using peripheral conductive pads and/or spacer material over the peripheral conductive pads as a planarization stop material. Yet further methods include partially defining memory cells in the array region, thereafter forming peripheral conductive contacts, and thereafter fully defining the memory cells.

An integrated circuit device includes a resistive random access memory (RRAM) cell or a MIM capacitor cell having a dielectric layer, a top conductive layer, and a bottom conductive layer. The dielectric layer includes a peripheral region adjacent an edge of the dielectric layer and a central region surrounded by the peripheral region. The top conductive layer abuts and is above dielectric layer. The bottom conductive layer abuts and is below the dielectric layer in the central region, but does not abut the dielectric layer the peripheral region of the cell. Abutment can be prevented by either an additional dielectric layer between the bottom conductive layer and the dielectric layer that is exclusively in the peripheral region or by cutting of the bottom electrode layer short of the peripheral region. Damage or contamination at the edge of the dielectric layer does not result in leakage currents.

A semiconductor memory device according to an embodiment includes: a semiconductor substrate which extends in first and second directions that intersect each other; a plurality of first wiring lines which are arranged in a third direction that intersects the first direction and the second direction, and which extend in the first direction; a plurality of second wiring lines which are arranged in the first direction and extend in the third direction; and a plurality of memory cells disposed at intersections of the first wiring lines and the second wiring lines, one of the memory cells having a first film whose resistance changes electrically, a thickness in the second direction of the first film changing with respect to a change of position in the third direction, and the first films of two of the memory cells adjacent in the third direction being separated between the two memory cells.

Some embodiments include apparatus and methods having a memory cell with a first electrode, a second electrode, and a dielectric located between the first and second electrodes. The dielectric may be configured to allow the memory cell to form a conductive path in the dielectric from a portion of a material of the first electrode to represent a first value of information stored in the memory cell. The dielectric may also be configured to allow the memory cell to break the conductive path to represent a second value of information stored in the memory cell.

A resistive random access memory is provided. The resistive random access memory includes a bottom electrode, a top electrode, a resistance changeable layer, an oxygen reservoir layer and a reactive oxygen barrier layer. The bottom electrode is disposed on a substrate. The top electrode is disposed above the bottom electrode. The resistance changeable layer is disposed between the bottom electrode and the top electrode. The oxygen reservoir layer is disposed between the resistance changeable layer and the top electrode. The reactive oxygen barrier layer is disposed inside the oxygen reservoir layer.

Devices and methods for forming a device are disclosed. The device includes a substrate and a selector diode disposed over the substrate. The diode includes first and second terminals. The first terminal is disposed between the second terminal and the substrate. The diode includes a Schottky Barrier (SB) disposed at about an interface of the first and second terminals. The SB includes a tunable SB height defined by a SB region having segregated dopants. The device includes a memory element disposed over and coupled to the selector diode.

Vertically stacked memory devices and methods of manufacture are provided. The structures include a substrate stack including a first row of horizontal electrodes disposed over a first insulating layer and first insulating layer disposed over a substrate. The substrate stack further includes a second row of horizontal electrodes separated from the first row of horizontal electrodes by a second insulating layer, and the first row of horizontal electrodes is form over and substantially parallel to the second row of horizontal electrodes. A third insulating layer is formed over the second row of horizontal electrodes. A plurality of vertical gate trenches formed through the third insulating layer, the second row of horizontal electrodes, the second insulating layer, the first row of horizontal electrodes and the first insulating layer. The plurality of vertical gate trenches filled with a layer of channel material, a layer of electrolyte material and filled with a metal.

A method of forming a memory device that includes depositing a first dielectric material within a trench of composed of a second dielectric material; positioning a nanotube within the trench using chemical recognition to the first dielectric material; depositing a dielectric for cation transportation within the trench on the nanotube; and forming a second electrode on the dielectric for cation transportation, wherein the second electrode is composed of a metal.

The lens unit includes a first lens array including a plurality of first lens elements each of which has a first optical axis and which are arranged in an arrangement direction perpendicular to the first optical axis. A second lens array includes a plurality of second lens elements each of which has a second optical axis and which are arranged in the arrangement direction while facing the first lens elements. The second lens array is in a positional relationship relative to the first lens array such that the second lens array is rotated about a virtual line perpendicular to both the first optical axis and the arrangement direction as the rotational axis by 180 degrees. The optical axes of the lens elements located at the substantially centers of the lens arrays in the arrangement direction are arranged to substantially coincide with each other.

A variable resistance memory device includes a first conductive line structure having an adiabatic line therein on a substrate, a variable resistance pattern contacting an upper surface of the first conductive line structure, a low resistance pattern contacting an upper surface of the variable resistance pattern, a selection structure on the low resistance pattern, and a second conductive line on the selection structure.