All-printed paper-based substrate memory devices are described. In an embodiment, a paper-based memory device is prepared by coating one or more areas of a paper substrate with a conductor material such as a carbon paste, to form a first electrode of a memory, depositing a layer of insulator material, such as titanium dioxide, over one or more areas of the conductor material, and depositing a layer of metal over one or more areas of the insulator material to form a second electrode of the memory. In an embodiment, the device can further include diodes printed between the insulator material and the second electrode, and the first electrode and the second electrodes can be formed as a crossbar structure to provide a WORM memory. The various layers and the diodes can be printed onto the paper substrate by, for example, an ink jet printer.

A method for treating a compound semiconductor substrate, in which method in vacuum conditions a surface of an In-containing III-As, III-Sb or III-P substrate is cleaned from amorphous native oxides and after that the cleaned substrate is heated to a temperature of about 250-550° C. and oxidized by introducing oxygen gas onto the surface of the substrate. The invention relates also to a compound semiconductor substrate, and the use of the substrate in a structure of a transistor such as MOSFET.

A method for treating a compound semiconductor substrate, in which method in vacuum conditions a surface of an In-containing III-As, III-Sb or III-P substrate is cleaned from amorphous native oxides and after that the cleaned substrate is heated to a temperature of about 250-550° C. and oxidized by introducing oxygen gas onto the surface of the substrate. The invention relates also to a compound semiconductor substrate, and the use of the substrate in a structure of a transistor such as MOSFET.

An advanced moisture resistant structure of compound semiconductor integrated circuit comprises a compound semiconductor substrate, a compound semiconductor epitaxial structure, a compound semiconductor integrated circuit and a moisture barrier layer. The compound semiconductor epitaxial structure is formed on the compound semiconductor substrate. The compound semiconductor integrated circuit is foimed on the compound semiconductor epitaxial structure. The moisture barrier layer is formed on the compound semiconductor integrated circuit. The moisture barrier layer is made of A1.sub.2O.sub.3. The thickness of the moisture barrier layer is greater than or equal to 400 Å and less than or equal to 1000 Å so as to enhance the moisture resistant ability of the compound semiconductor integrated circuit.

A method of forming a semiconductor device includes forming active regions, forming S/D regions, forming MD contact structures and forming gate lines resulting in corresponding transistors that define a first time delay circuit having a first input configured to receive a first clock signal and having a first output configured to generate a second clock signal from the first clock signal; and corresponding transistors that define a second time delay circuit having a second input configured to receive the second clock signal and having a second output configured to generate a third clock signal from the first clock signal; forming a first gate via-connector in direct contact with the first gate line atop the first-type active region in the first area; and forming a second gate via-connector in direct contact with the second gate line atop the second-type active region in the second area.

One illustrative transistor device disclosed herein includes a gate structure positioned above a semiconductor substrate and a source region and a drain region, each of which comprise an epi cavity with a bottom surface and a side surface. The transistor further includes an interface layer positioned on at least one of the side surface and the bottom surface of the epi cavity in each of the source/drain regions, wherein the interface layer comprises a non-semiconductor material and an epi semiconductor material positioned on at least an upper surface of the interface layer in the epi cavity in each of the source region and the drain region.

A semiconductor device having first through third layers. The first layer has a conductivity type that is different from a conductivity type of the second layer. A peak value of an impurity concentration of a portion of the third layer is greater than a peak value of an impurity concentration of the second layer. The semiconductor device allows a decrease in the forward voltage drop and also allows an improvement of the safe operating area tolerance. Thus, it is possible to decrease the forward voltage drop, improve the maximum reverse voltage, and suppress oscillations at the time of recovery.

An RRAM structure includes a substrate. The substrate is divided into a memory cell region and a logic device region. A metal plug is disposed within the memory cell region. An RRAM is disposed on and contacts the metal plug. The RRAM includes a top electrode, a variable resistive layer, and a bottom electrode. The variable resistive layer is disposed between the top electrode and the bottom electrode. The variable resistive layer includes a first bottom surface. The bottom electrode includes a first top surface. The first bottom surface and the first top surface are coplanar. The first bottom surface only overlaps and contacts part of the first top surface.

Provided are memory cells, such as resistive random access memory (ReRAM) cells, each cell having multiple metal oxide layers formed from different oxides, and methods of manipulating and fabricating these cells. Two metal oxides used in the same cell have different dielectric constants, such as silicon oxide and hafnium oxide. The memory cell may include electrodes having different metals. Diffusivity of these metals into interfacing metal oxide layers may be different. Specifically, the lower-k oxide may be less prone to diffusion of the metal from the interfacing electrode than the higher-k oxide. The memory cell may be formed to different stable resistive levels and then resistively switched at these levels. Each level may use a different switching power. The switching level may be selected a user after fabrication of the cell and in, some embodiments, may be changed, for example, after switching the cell at a particular level.

A semiconductor device includes a drift layer disposed on a substrate. The drift layer has a non-planar surface having a plurality of repeating features oriented parallel to a length of a channel of the semiconductor device. Further, each the repeating features have a dopant concentration higher than a remainder of the drift layer.