A method of manufacturing a semiconductor device includes a semiconductor region forming process, a cleaning process, a surface roughness uniformizing process, and an electrode forming process. As the semiconductor region forming process, semiconductor regions are formed such that a plurality of semiconductor regions with different ion injection amounts are exposed on one principal surface of a semiconductor substrate. As the cleaning process, after the semiconductor region forming process, a cleaning using hydrofluoric acid is performed on the one principal surface of the semiconductor substrate. As the surface roughness uniformizing process, after the cleaning process, the surface roughness of the one principal surface of the semiconductor substrate is uniformized. As the electrode forming process, after the surface roughness uniformizing process, electrodes are formed on the one principal surface of the semiconductor substrate.

A SiC epitaxial wafer including: a SiC epitaxial layer that is formed on a SiC substrate having an off angle, wherein the surface density of triangular defects, in which a distance from a starting point to an opposite side in a horizontal direction is equal to or greater than (a thickness of the SiC epitaxial layer/tan(x))90% and equal to or less than (the thickness of the SiC epitaxial layer/tan(x))110%, in the SiC epitaxial layer is in the range of 0.05 pieces/cm.sup.2 to 0.5 pieces/cm.sup.2 (where x indicates the off angle).

The present invention provides a semiconductor device, including a substrate, two gate structures disposed on a channel region of the substrate, an epitaxial layer disposed in the substrate between two gate structures, a first dislocation disposed in the epitaxial layer, wherein the profile of the first dislocation has at least two non-parallel slanting lines, and a second dislocation disposed adjacent to a top surface of the epitaxial layer, and the profile of the second dislocation has at least two non-parallel slanting lines.

According to various embodiments, a method may include: structuring a semiconductor region to form a structured surface of the semiconductor region; disposing a dopant in the semiconductor region; and activating the dopant at least partially by irradiating the structured surface at least partially with electromagnetic radiation having at least one discrete wavelength to heat the semiconductor region at least partially.

An insulating layer is formed on a substrate made of silicon carbide. By performing etching using a mask layer formed on the insulating layer, a contact hole is formed in the insulating layer to expose a contact region, which is a portion of a main surface of the substrate. The step of forming the contact hole includes a step of providing the contact region with a surface roughness Ra of not less than 0.5 nm. An electrode layer is formed in contact with the contact region. By heating the electrode layer and the substrate, siliciding reaction is caused between the electrode layer and the contact region.

According to various embodiments, a method may include: structuring a semiconductor region to form a structured surface of the semiconductor region; disposing a dopant in the semiconductor region; and activating the dopant at least partially by irradiating the structured surface at least partially with electromagnetic radiation having at least one discrete wavelength to heat the semiconductor region at least partially.

A method of manufacturing a semiconductor device includes a semiconductor region forming process, a cleaning process, a surface roughness uniformizing process, and an electrode forming process. As the semiconductor region forming process, semiconductor regions are formed such that a plurality of semiconductor regions with different ion injection amounts are exposed on one principal surface of a semiconductor substrate. As the cleaning process, after the semiconductor region forming process, a cleaning using hydrofluoric acid is performed on the one principal surface of the semiconductor substrate. As the surface roughness uniformizing process, after the cleaning process, the surface roughness of the one principal surface of the semiconductor substrate is uniformized. As the electrode forming process, after the surface roughness uniformizing process, electrodes are formed on the one principal surface of the semiconductor substrate.

Provided is a method of manufacturing a SiC epitaxial wafer including a SiC epitaxial layer on a SiC substrate using a SiC-CVD furnace which is installed in a glove box. The method includes a SiC substrate placement step of placing the SiC substrate in the SiC-CVD furnace while circulating gas in the glove box.

A device having a layer with a patterned surface for improving the growth of semiconductor layers, such as group III nitride-based semiconductor layers with a high concentration of aluminum, is provided. The patterned surface can include a substantially flat top surface and a plurality of stress reducing regions, such as openings. The substantially flat top surface can have a root mean square roughness less than approximately 0.5 nanometers, and the stress reducing regions can have a characteristic size between approximately 0.1 microns and approximately five microns and a depth of at least 0.2 microns. A layer of group-III nitride material can be grown on the first layer and have a thickness at least twice the characteristic size of the stress reducing regions.

A method of reducing defects in epitaxially grown III-V semiconductor material comprising: epitaxially growing a III-V semiconductor on a substrate; patterning and removing portions of the III-V semiconductor to form openings; depositing thermally stable material in the openings; depositing a capping layer over the semiconductor material and thermally stable material to form a substantially enclosed semiconductor; and annealing the substantially enclosed semiconductor.