In a processing method of a stacked-layer film in which a metal film is provided on an oxide insulating film, plasma containing an oxygen ion is generated by applying high-frequency power with power density greater than or equal to 0.59 W/cm.sup.2 and less than or equal to 1.18 W/cm.sup.2 to the stacked-layer film side under an atmosphere containing oxygen in which pressure is greater than or equal to 5 Pa and less than or equal to 15 Pa, the metal film is oxidized by the oxygen ion, and an oxide insulating film containing excess oxygen is formed by supplying oxygen to the oxide insulating film.

A Method for producing a layer of strained semiconductor material, the method comprising steps for: a) formation on a substrate of a stack comprising a first semiconductor layer based on a first semiconductor material coated with a second semiconductor layer based on a second semiconductor material having a different lattice parameter to that of the first semiconductor material, b) producing on the second semiconductor layer a mask having a symmetry, c) rendering amorphous the first semiconductor layer along with zones of the second semiconductor layer without rendering amorphous one or a plurality of regions of the second semiconductor layer protected by the mask and arranged respectively opposite the masking block(s), d) performing recrystallization of the regions rendered amorphous and the first semiconductor layer resulting in this first semiconductor layer being strained (FIG. 1A).

The present polymeric materials can be patterned with relatively low photo-exposure energies and are thermally stable, mechanically robust, resist water penetration, and show good adhesion to metal oxides, metals, metal alloys, as well as organic materials. In addition, these polymeric materials can be solution-processed (e.g., by spin-coating), and can exhibit good chemical (e.g., solvent and etchant) resistance in the cured form.

A change in electrical characteristics in a semiconductor device including an oxide semiconductor film is inhibited, and the reliability is improved. The semiconductor device includes a gate electrode, a first insulating film over the gate electrode, an oxide semiconductor film over the first insulating film, a source electrode electrically connected to the oxide semiconductor film, a drain electrode electrically connected to the oxide semiconductor film, a second insulating film over the oxide semiconductor film, the source electrode, and the drain electrode, a first metal oxide film over the second insulating film, and a second metal oxide film over the first metal oxide film. The first metal oxide film contains at least one metal element that is the same as a metal element contained in the oxide semiconductor film. The second metal oxide film includes a region where the second metal oxide film and the first metal oxide film are mixed.

The invention relates to a method for fabricating a semiconductor circuit comprising providing a semiconductor substrate; fabricating a first semiconductor device comprising a first semiconductor material on the substrate and forming an insulating layer comprising a cavity structure on the first semiconductor device. The cavity structure comprises at least one growth channel and the growth channel connects a crystalline seed surface of the first semiconductor device with an opening. Further steps include growing via the opening from the seed surface a semiconductor filling structure comprising a second semiconductor material different from the first semiconductor material in the growth channel; forming a semiconductor starting structure for a second semiconductor device from the filling structure; and fabricating a second semiconductor device comprising the starting structure. The invention is notably also directed to corresponding semiconductor circuits.

Methods of forming and resulting devices are described that include graphene devices on boron nitride. Selected methods of forming and resulting devices include graphene field effect transistors (GFETs) including boron nitride.

A thin film transistor and manufacturing method thereof, an array substrate and a display device are provided. In the manufacturing method of the thin film transistor, manufacturing an active layer includes: forming a germanium thin film, and forming pattern of the active layer through a patterning process; conducting a topological treatment on the germanium thin film with a functionalized element, so as to obtain the active layer (4) with topological semiconductor characteristics. The resultant thin film transistor has a higher carrier mobility and a better performance.

A threshold voltage tuning approach for forming a stacked nanowire gate-all around pFET is provided. In the present application, selective condensation (i.e., oxidation) is used to provide a threshold voltage shift in silicon germanium alloy nanowires. The threshold voltage shift is well controlled because both underlying parameters which govern the final germanium content, i.e., nanowire width and amount of condensation, are well controlled by the selective condensation process. The present application can address the problem of width quantization in stacked nanowire FETs by offering various device options.

A TFT includes a substrate, a gate, a gate insulating layer, a semiconductor oxide layer, a source/drain layer, a passivation layer, and a transparent conducting layer arranged from bottom to top. An etching block layer is formed after the source/drain layer arranged on the semiconductor oxide layer is etched. A method for forming for the TFT includes: depositing and photo-etching a gate on a substrate; depositing a gate insulating layer on the gate; depositing and photo-etching a semiconductor oxide layer on the gate insulating layer; depositing and photo-etching a source/drain layer on the semiconductor oxide layer; etching the source/drain layer on the semiconductor oxide layer for forming an etching block layer; depositing a passivation layer on the source/drain layer and the semiconductor oxide layer; depositing a transparent conducting layer on the passivation layer.

A thin-film transistor (TFT) switch includes a gate, a drain, a source, a semiconductor layer, and a fourth electrode. The drain is connected to a first signal. The gate is connected to a control signal to control the switch on or off. The source outputs the first signal when the switch turns on. The fourth electrode and the gate are respectively located at two sides of the semiconductor layer. The fourth electrode is conductive and is selectively coupled to different voltage levels, thereby reducing leakage current in a channel to improve switch characteristic when the switch turns off.