Provided is a machining apparatus including a profile sensor unit configured to obtain shape information about a parent substrate; and a laser scan unit configured to direct a laser beam onto the parent substrate, wherein a laser beam axis of the laser beam is tilted to an exposed main surface of the parent substrate, and wherein a track of the laser beam on the parent substrate is controllable as a function of the shape information obtained from the profile sensor unit.

Techniques for processing materials for manufacture of gallium-containing nitride substrates are disclosed. More specifically, techniques for fabricating and reusing large area substrates using a combination of processing techniques are disclosed. The methods can be applied to fabricating substrates of GaN, AlN, InN, InGaN, AlGaN, and AlInGaN, and others. Such substrates can be used for a variety of applications including optoelectronic devices, lasers, light emitting diodes, solar cells, photo electrochemical water splitting and hydrogen generation, photo detectors, integrated circuits, transistors, and others.

A process for transferring blocks from a donor to a receiver substrate, comprises: arranging a mask facing a free surface of the donor substrate, the mask having one or more openings that expose the free surface of the donor substrate, the openings distributed according to a given pattern; forming, by ion implantation through the mask, an embrittlement plane in the donor substrate vertically in line with at least one region exposed through the mask, the embrittlement plane delimiting a respective surface region; forming a block that is raised relative to the free surface of the donor substrate localized vertically in line with each respective embrittlement plane, the block comprising the respective surface region; bonding the donor substrate to the receiver substrate via each block located at the bonding interface, after removing the mask; and detaching the donor substrate along the localized embrittlement planes to transfer blocks onto the receiver substrate.

A glass substrate contains, as a glass matrix composition as represented by mole percentage based on oxides, SiO.sub.2: 58-75%, Al.sub.2O.sub.3: 4.5-16%, B.sub.2O.sub.3: 0-6%, MgO: 0-6%, CaO: 0-6%, SrO: 5-20%, BaO: 5-20%, and MgO+CaO+SrO+BaO:15-40%. The glass substrate has an alkali metal oxide content of 0-0.1% as represented by mole percentage based on oxides. The glass substrate has an average coefficient of thermal expansion α of 56-90 (×10.sup.−7/° C.) at 50° C.-350° C.

A method for processing a semiconductor wafer is provided. A semiconductor wafer includes a first main surface and a second main surface. Defects are generated inside the semiconductor wafer to define a detachment plane parallel to the first main surface. Processing the first main surface defines a plurality of electronic semiconductor components. A glass structure is provided which includes a plurality of openings. The glass structure is attached to the processed first main surface, each of the plurality of openings leaving a respective area of the plurality of electronic semiconductor components uncovered. A polymer layer is applied to the second main surface and the semiconductor wafer is split into a semiconductor slice and a remaining semiconductor wafer by cooling the polymer layer beneath its glass transition temperature along the detachment plane. The semiconductor slice includes the plurality of electronic semiconductor components.

Disclosed herein are compositions, methods and devices that allow for water-soluble epitaxial lift-off of III-V. Epitaxial growth of STO/SAO templates on STO (001) and Ge (001) substrates were demonstrated. Partially epitaxial GaAs growth was achieved on STO/SAO/STO substrate templates.

A method includes: providing a layer of porous silicon carbide supported by a silicon carbide substrate; providing a layer of epitaxial silicon carbide on the layer of porous silicon carbide; forming semiconductor devices in the layer of epitaxial silicon carbide; and separating the silicon carbide substrate from the layer of epitaxial silicon carbide at the layer of porous silicon carbide. The layer of porous silicon carbide includes dopants defining a resistivity of the layer of porous silicon carbide. The resistivity of the layer of porous silicon carbide is different from a resistivity of the silicon carbide substrate. Additional methods are described.

A semiconductor chip includes: an epitaxial film made of gallium nitride; a semiconductor element disposed in the epitaxial film; a chip formation substrate including the epitaxial film and having a first surface, a second surface opposite to the first surface, and a side surface connecting the first surface and the second surface; and a convex and a concavity on the side surface.

A gallium nitride semiconductor device includes: a chip formation substrate made of gallium nitride and having one surface and an other surface opposite to the one surface; a one surface side element component disposed on the one surface and providing a component of an one surface side of a semiconductor element; and a metal film constituting a back surface electrode in contact with the other surface. The other surface has an irregularity provided by a plurality of convex portions with a trapezoidal cross section and a plurality of concave portions located between the convex portions; and an upper base surface of the trapezoidal cross section in each of the plurality of convex portions is opposed to the one surface.

A method for manufacturing a semiconductor device includes a step of preparing a semiconductor wafer source which includes a first main surface on one side, a second main surface on the other side and a side wall connecting the first main surface and the second main surface, an element forming step of setting a plurality of element forming regions on the first main surface of the semiconductor wafer source, and forming a semiconductor element at each of the plurality of element forming regions, and a wafer source separating step of cutting the semiconductor wafer source from a thickness direction intermediate portion along a horizontal direction parallel to the first main surface, and separating the semiconductor wafer source into an element formation wafer and an element non-formation wafer after the element forming step.