A resistive random access memory is provided. The resistive random access memory includes a bottom electrode, a top electrode, a resistance-switching layer, an oxygen exchange layer, and a sidewall protective layer. The bottom electrode is disposed over a substrate. The top electrode is disposed over the bottom electrode. The resistance-switching layer is disposed between the bottom electrode and the top electrode. The oxygen exchange layer is disposed between the resistance-switching layer and the top electrode. The sidewall protective layer as an oxygen supply layer is at least disposed at sidewalls of the oxygen exchange layer.

A photodetector comprising a region of a p-type phase-change chalcogenide material forming a heterojunction with a region of n-type Silicon; wherein the p-type phase-change chalcogenide material comprises one of GeTe and SbTe.

The present disclosure relates to an integrated circuit, which includes a semiconductor substrate and an interconnect structure disposed over the semiconductor substrate. The interconnect structure includes a lower metal layer, an intermediate metal layer disposed over the lower metal layer, and an upper metal layer disposed over the intermediate metal layer. An upper surface of the lower metal layer and a lower surface of the intermediate metal layer are spaced vertically apart by a first distance. A resistive random access memory (RRAM) cell is arranged between the lower metal layer and the upper metal layer. The RRAM cell includes a bottom electrode and a top electrode which are separated by a data storage layer having a variable resistance. The data storage layer vertically spans a second distance that is greater than the first distance.

A device includes an upper metallic layer, a lower layer, and a nano sensor array positioned between the upper and lower layers to detect a presence of a gas, a chemical, or a biological object, wherein each sensor's electrical characteristic changes when encountering the gas, chemical or biological object.

The present disclosure generally relates to fine geometry electrical circuits and methods of manufacture thereof. More specifically, methods for forming 3D cross-point memory arrays using a single nano-imprint lithography step and no photolithography are disclosed. The method includes imprinting a multilevel topography pattern, transferring the multilevel topography pattern to a substrate, filling the etched multilevel topography pattern with hard mask material, planarizing the hard mask material to expose a first portion of the substrate, etching a first trench in the first portion of the substrate, depositing a first plurality of layers in the first trench, planarizing the hard mask material to expose a second portion of the substrate, etching a second trench in the second portion of the substrate and depositing a second plurality of layers in the second trench. The method is repeated until a 4F.sup.2 3D cross-point memory array has been formed.

A semiconductor device according to the embodiment includes a plurality of semiconductor layers arranged along a first direction and a second direction, wherein each of the semiconductor layers includes a first semiconductor layer and second semiconductor layers positioned at both upper and lower sides of the first semiconductor layer, and a gate electrode which faces the first semiconductor layer. A row of the semiconductor layer in the first direction is oblique to a row of the semiconductor layer in the second direction. At least one part of peripheral faces of the first semiconductor layer is in contact with the gate electrode along the first direction.

Disclosed herein are resistive switching devices having, e.g., an amorphous layer comprised of an insulating aluminum-based or silicon-based material and a conducting material. The amorphous layer may be disposed between two or more electrodes and be capable of switching between at least two resistance states. Circuits and memory devices including resistive switching devices are also disclosed, and a composition of matter involving an insulating aluminum-based or an silicon-based material and a conducting material. Also disclosed herein are methods for switching the resistance of an amorphous material.

A transparent conductive film includes a metal oxide, a metal, and an epoxy, wherein a refractive index of the metal may be lower than that of the epoxy.

Provided are a semiconductor device and a method of fabricating the same. The semiconductor device may include a selection element, a lower electrode pattern provided on the selection element to include a horizontal portion and a vertical portion; and a phase-changeable pattern on the lower electrode pattern. The vertical portion may extend from the horizontal portion toward the phase-changeable pattern and have a top surface, whose area is smaller than that of a bottom surface of the phase-changeable pattern.

The present disclosure relates an integrated circuit (IC). The IC comprises a memory region and a logic region. A lower metal layer is disposed over a substrate, and comprises a first lower metal line within the memory region. An upper metal layer overlies the lower metal layer, and comprises a first upper metal line within the memory region. A memory cell is disposed between the first lower metal line and the first upper metal line, and comprises a planar bottom electrode. The planar bottom electrode abuts a first lower metal via of the lower metal layer. By forming the planar bottom electrode and connecting the planar bottom electrode to the lower metal layer through the lower metal via, no additional BEVA planarization and/or patterning processes are needed. As a result, risk of damaging the lower metal lines are reduced, thereby providing more reliable read/write operations and/or better performance.