A method includes depositing a silicon layer, which includes first portions over a plurality of strips, and second portions filled into trenches between the plurality of strips. The plurality of strips protrudes higher than a base structure. The method further includes performing an anneal to allow parts of the first portions of the silicon layer to migrate toward lower parts of the plurality of trenches, and performing an etching on the silicon layer to remove some portions of the silicon layer.

A semiconductor device includes a semiconductor substrate, a transistor section, a diode section, and a boundary section provided between the transistor section and the diode section in the semiconductor substrate. The transistor section has gate trench portions which are provided from an upper surface of the semiconductor substrate to a position deeper than that of an emitter region, and to each of which a gate potential is applied. An upper-surface-side lifetime reduction region is provided on the upper surface side of the semiconductor substrate in the diode section and a partial region of the boundary section, and is not provided in a region that is overlapped with the gate trench portion in the transistor section in a surface parallel to the upper surface of the semiconductor substrate.

A semiconductor device includes a semiconductor substrate, a transistor section, a diode section, and a boundary section provided between the transistor section and the diode section in the semiconductor substrate. The transistor section has gate trench portions which are provided from an upper surface of the semiconductor substrate to a position deeper than that of an emitter region, and to each of which a gate potential is applied. An upper-surface-side lifetime reduction region is provided on the upper surface side of the semiconductor substrate in the diode section and a partial region of the boundary section, and is not provided in a region that is overlapped with the gate trench portion in the transistor section in a surface parallel to the upper surface of the semiconductor substrate.

A method for manufacturing a silicon single-crystal substrate having a carbon diffusion layer on a surface, proximity gettering ability, and high strength near the surface, and hardly generating dislocation or extending dislocation, includes: a step of adhering carbon on a surface of a silicon single-crystal substrate by an RTA treatment of the silicon single-crystal substrate in a carbon-containing gas atmosphere; a step of forming a 3C-SiC single-crystal film on the surface of the silicon single-crystal substrate by reacting the carbon and the silicon single-crystal substrate; a step of oxidizing the 3C-SiC single-crystal film to be an oxide film and diffusing carbon inward the silicon single-crystal substrate by an RTA treatment of the silicon single-crystal substrate on which the 3C-SiC single-crystal film is formed, the RTA treatment being performed in an oxidative atmosphere; and a step of removing the oxide film.

A method of forming an integrated circuit that includes placing a semiconductor substrate in a process chamber at an initial temperature, wherein one or more trenches are located within the semiconductor substrate. The temperature of the substrate is increased in a substantially oxygen-free ambient to an oxide-growth temperature. The temperature is then maintained at the oxide growth temperature while providing an oxidizing ambient, thereby forming an oxide layer on sidewalls of the trench. The temperature of the semiconductor wafer is then reduced to a final temperature below the initial temperature and removed from the process chamber.

A method of forming an integrated circuit that includes placing a semiconductor substrate in a process chamber at an initial temperature, wherein one or more trenches are located within the semiconductor substrate. The temperature of the substrate is increased in a substantially oxygen-free ambient to an oxide-growth temperature. The temperature is then maintained at the oxide growth temperature while providing an oxidizing ambient, thereby forming an oxide layer on sidewalls of the trench. The temperature of the semiconductor wafer is then reduced to a final temperature below the initial temperature and removed from the process chamber.

A silicon wafer having a layer of oxygen precipitates and method of manufacturing thereof wherein the wafer exhibiting robustness characterized as having a ratio of a first average density from a first treatment that to a second average density from a second treatment is between 0.74 to 1.02, wherein the first treatment includes heating the wafer or a portion of the wafer at about 1150° C. for about 2 minutes and then between about 950 to 1000° C. for about 16 hours, and the second treatment includes heating the wafer or a portion of the wafer at about 780° C. for about 3 hours and then between about 950 to 1000° C. for about 16 hours. The wafer exhibits heretofore unattainable uniformity wherein a ratio of an oxygen precipitate density determined from any one cubic centimeter in the BMD layer of the wafer to another oxygen precipitate density from any other one cubic centimeter in the BMD layer of the wafer is in a range of 0.77 to 1.30.

A method of processing and passivating an implanted workpiece is disclosed, wherein, after passivation, the fugitive emissions of the workpiece are reduced to acceptably low levels. This may be especially beneficial when phosphorus, arsine, germane or another toxic species is the dopant being implanted into the workpiece. In one embodiment, a sputtering process is performed after the implantation process. This sputtering process is used to sputter the dopant at the surface of the workpiece, effectively lowering the dopant concentration at the top surface of the workpiece. In another embodiment, a chemical etching process is performed to lower the dopant concentration at the top surface. After this sputtering or chemical etching process, a traditional passivation process can be performed.

An epitaxy substrate and a method of manufacturing the same are provided. The epitaxy substrate includes a silicon substrate and a silicon carbide layer. The silicon substrate has a first surface and a second surface opposite to each other, and the first surface is an epitaxy surface. The silicon carbide layer is located in the silicon substrate, and a distance between the silicon carbide layer and the first surface is between 100 angstroms (Å) and 500 angstroms.

A semiconductor-on-insulator (e.g., silicon-on-insulator) structure having superior radio frequency device performance, and a method of preparing such a structure, is provided by utilizing a single crystal silicon handle wafer sliced from a float zone grown single crystal silicon ingot.