A photoelectric conversion device has a silicon substrate which includes a first portion configured to perform photoelectric conversion, and a second portion which is arranged farther apart from a light receiving surface of the silicon substrate than the first portion and contains carbon. A first peak concentration as a carbon peak concentration in the second portion is not less than 110.sup.18 [atoms/cm.sup.3] and not more than 110.sup.20 [atoms/cm.sup.3], and a second peak concentration as an oxygen peak concentration in the second portion is not less than 1/1000 and not more than 1/10 of the first peak concentration.

A compound semiconductor has a high electron concentration of 5?10.sup.19 cm.sup.?3 or higher, exhibits an electron mobility of 46 cm.sup.2/V.Math.s or higher, and exhibits a low electric resistance, and thus is usable to produce a high performance semiconductor device. The present invention provides a group 13 nitride semiconductor of n-type conductivity that may be formed as a film on a substrate having a large area size at a temperature of room temperature to 700? C.

Processing chamber components and methods of manufacture of same are provided herein. In some embodiments, a component part body includes a component part body having a base plane and at least one textured surface region, wherein the at least one textured surface region comprises a plurality of independent surface features having a first side having at least a 45 degree angle with respect to the base plane. In at least some embodiments, the textured surface includes a plurality of independent surface features which are pore free.

A photonic structure can include in one aspect one or more waveguides formed by patterning of waveguiding material adapted to propagate light energy. Such waveguiding material may include one or more of silicon (single-, poly-, or non-crystalline) and silicon nitride.

A method for preparing a ceramic package substrate with a copper-plated dam involves making a circuit layer on a ceramic base by performing thin film metallization, dry film application, exposure, development, copper plating, and evening, and then forming copper-plated dams that circle individual circuits by repeatedly applying dry film application, exposure, development, and electroplating for thickening, so as to obtain the ceramic package substrate with the copper-plated dam. Circuits made using the method feature for high dimensional precision, high line resolution, and high surface evenness.

A pressurizing device includes: a mounting base; an upper mold which pressurizes the target object mounted on the mounting base from above; a heating lower mold which is a lower mold heated in advance by a heater, and which heats the target object under pressure by sandwiching the mounting base with the upper mold; a cooling lower mold which is a lower mold cooled in advance by a cooler, and which cools the target object under pressure by sandwiching the mounting base with the upper mold; and a control device which switches the lower mold that contributes to the pressurization of the target object to the heating lower mold or the cooling lower mold in accordance with the status of progress of the pressurization process for the target object.

In one instance, the seed crystal of this invention provides a nitrogen-polar c-plane surface of a GaN layer supported by a metallic plate. The coefficient of thermal expansion of the metallic plate matches that of GaN layer. The GaN layer is bonded to the metallic plate with bonding metal. The bonding metal not only bonds the GaN layer to the metallic plate but also covers the entire surface of the metallic plate to prevent corrosion of the metallic plate and optionally spontaneous nucleation of GaN on the metallic plate during the bulk GaN growth in supercritical ammonia. The bonding metal is compatible with the corrosive environment of ammonothermal growth.

In one instance, the seed crystal of this invention provides a nitrogen-polar c-plane surface of a GaN layer supported by a metallic plate. The coefficient of thermal expansion of the metallic plate matches that of GaN layer. The GaN layer is bonded to the metallic plate with bonding metal. The bonding metal not only bonds the GaN layer to the metallic plate but also covers the entire surface of the metallic plate to prevent corrosion of the metallic plate and optionally spontaneous nucleation of GaN on the metallic plate during the bulk GaN growth in supercritical ammonia. The bonding metal is compatible with the corrosive environment of ammonothermal growth.

A composition of matter comprising a plurality of nanowires on a substrate, said nanowires having been grown epitaxially on said substrate in the presence of a metal catalyst such that a catalyst deposit is located at the top of at least some of said nanowires, wherein said nanowires comprise at least one group III-V compound or at least one group II-VI compound or comprises at least one non carbon group IV element; and wherein a graphitic layer is in contact with at least some of the catalyst deposits on top of said nanowires.

In one instance, the seed crystal of this invention provides a nitrogen-polar c-plane surface of a GaN layer supported by a metallic plate. The coefficient of thermal expansion of the metallic plate matches that of GaN layer. The GaN layer is bonded to the metallic plate with bonding metal. The bonding metal not only bonds the GaN layer to the metallic plate but also covers the entire surface of the metallic plate to prevent corrosion of the metallic plate and optionally spontaneous nucleation of GaN on the metallic plate during the bulk GaN growth in supercritical ammonia. The bonding metal is compatible with the corrosive environment of ammonothermal growth.