A process for growing nanowires or nanopyramids comprising: (I) providing a graphitic substrate and depositing AlGaN, InGaN, AlN or AlGa(In)N on said graphitic substrate at an elevated temperature to form a buffer layer or nanoscale nucleation islands of said compounds; (II) growing a plurality of semiconducting group III-V nanowires or nanopyramids, preferably III-nitride nanowires or nanopyramids, on the said buffer layer or nucleation islands on the graphitic substrate, preferably via MOVPE or MBE.

Photoactive silicon films may be formed by electrodeposition from a molten salt electrolyte. In an embodiment, SiO.sub.2 is electrochemically reduced in a molten salt bath to deposit silicon on a carbonaceous substrate.

A semiconductor structure includes an insulating substrate, an engineered layer, a semiconductor layer, and an isolation structure. The engineered layer is surrounding the insulating substrate. The semiconductor layer, which includes a first region and a second region,. is formed over the engineered layer. The isolation structure is formed in the semiconductor layer and located between the first region and the second region. A first transistor and a second transistor are formed in the first region and the second region respectively.

A method of positioning nanomaterials includes patterning guiding dielectric features from a single layer of guiding dielectric material, and producing an electric field by at least one electrode disposed on a substrate that is attenuated through the guiding dielectric features to create an attractive dielectrophoretic force that guides at least one nanostructure abutting the guiding dielectric features to be positioned on a deposition surface of the substrate.

A SiC epitaxial wafer includes: a substrate having an off angle of less than 4 degrees; and a SiC epitaxial growth layer disposed on the substrate having the off angle of less than 4 degrees, wherein an Si compound is used for a supply source of Si, and a C compound is used as a supply source of C, for the SiC epitaxial growth layer, wherein the uniformity of carrier density is less than 10%, and the defect density is less than 1 count/cm.sup.2; and a C/Si ratio of the Si compound and the C (carbon) compound is within a range of 0.7 to 0.95. There is provide a high-quality SiC epitaxial wafer excellent in film thickness uniformity and uniformity of carrier density, having the small number of surface defects, and capable of reducing costs, also in low-off angle SiC substrates on SiC epitaxial growth.

A method of forming an epitaxial layer on a substrate such as a sapphire wafer that does not readily absorb thermal radiation. The method includes coating a first side surface of the substrate with an energy-absorbing opaque material. The opaque material forms a thermally absorptive coating on the substrate. The coated substrate may be heated to remove contaminants from the thermally absorptive coating. The coated substrate is positioned in a vacuum deposition chamber and heated by directing radiative energy onto the thermally absorptive coating. An epitaxial layer such as GaN or SiGe is formed on a second side surface of the substrate opposite the thermally absorptive coating.

A composition of matter comprising a film on a graphitic substrate, said film having been grown epitaxially on said substrate, wherein said film comprises at least one group III-V compound or at least one group II-VI compound.

A method for fabricating an electrically isolated diamond nanowire includes forming a diamond nanowire on a diamond substrate, depositing a dielectric or a polymer on the diamond nanowire and on the diamond substrate, planarizing the dielectric or the polymer, etching a portion of the planarized dielectric or polymer to expose a first portion of the diamond nanowire, depositing a metal layer to conformably cover the first portion of the diamond nanowire, and implanting ions into a second portion of the diamond nanowire between the first portion of the diamond nanowire and the diamond substrate or at an intersection of the diamond nanowire and the diamond substrate, wherein the ions are implanted at an oblique angle from a first side of the diamond nanowire.

A diamond substrate producing method includes a belt-shaped separation layer forming step of applying a laser beam to a diamond ingot as relatively moving the ingot and a focal point of the laser beam in a [110]-direction perpendicular to a (110)-plane, thereby forming a belt-shaped separation layer extending in the [110]-direction inside the ingot, an indexing step of relatively moving the ingot and the focal point in an indexing direction parallel to a (001)-plane and perpendicular to the [110]-direction, a planar separation layer forming step of repeating the belt-shaped separation layer forming step and the indexing step to thereby form a planar separation layer parallel to the (001)-plane inside the ingot, the planar separation layer being composed of a plurality of belt-shaped separation layers arranged side by side in the indexing direction, and a separating step of separating a substrate from the diamond ingot along the planar separation layer.

The present invention relates to semiconductor manufacturing parts used in a dry etching process. Semiconductor manufacturing parts comprising a SiC deposition layer, of the present invention, comprises: a base material; and a SiC deposition layer formed on the surface of the base material, wherein the thickness ratio of the base material and the SiC deposition layer is 2:1 to 100:1.