A method for producing a wafer layer, including the method steps of: A) providing a carrier element; B) making the carrier element porous on at least one surface in order to produce a separating layer; C) applying a wafer layer to the separating layer of the carrier element by epitaxy; and D) detaching the wafer layer from the carrier element, with method steps B to D being repeated at least once, preferably multiple times, with the carrier element. The method step A includes the additional method steps of: A1) providing a carrier substrate; and A2) applying a seed layer to at least one surface and at least one lateral face of the carrier substrate by epitaxy in order to produce the carrier element. A carrier element for producing a wafer layer and an intermediate product are also provided.

A method for forming a high resistivity handle substrate for a composite substrate comprises: providing a base substrate made of silicon; exposing the base substrate to a carbon single precursor at a pressure below atmospheric pressure to form a polycrystalline silicon carbide layer having a thickness of at least 10 nm on the surface of the base substrate; and then growing a polycrystalline charge trapping layer on the carbon-containing layer.

The present disclosure relates to a method for transferring a target layer to a substrate. The method includes providing a stack by forming a first transfer layer over a first substrate, forming a second transfer layer on the first transfer layer, the second transfer layer being water-soluble, and forming the target layer on the second transfer layer, such that the stack has a top surface. The method also includes bonding the top surface of the stack to a second substrate, separating the first transfer layer from the second transfer layer, and dissolving the second transfer layer in water.

A method for manufacturing a relaxed epitaxial InGaN layer from a GaN/InGaN substrate comprising the following steps: a) providing a first stack comprising a GaN or InGaN layer to be porosified and a barrier layer, b) transferring the GaN or InGaN layer to be porosified and the barrier layer to a porosification support, in such a way as to form a second stack, c) forming a mask on the GaN or InGaN layer to be porosified, d) porosifying the GaN or InGaN layer through the mask, e) transferring the GaN or InGaN porosified layer and the barrier layer to a support of interest, f) forming an InGaN layer by epitaxy on the barrier layer, whereby a relaxed epitaxial InGaN layer is obtained.

A composite substrate is provided in some embodiments of the present disclosure, which includes a substrate, an insulation layer, a first silicon-containing layer and a first epitaxial layer. The insulation layer is disposed on the substrate. The first silicon-containing layer is disposed on the insulation layer, in which the first silicon-containing layer includes a plurality of group V atoms. The first epitaxial layer is disposed on the first silicon-containing layer, in which the first epitaxial layer includes a plurality of group III atoms. A distribution concentration of the group V atoms in the first silicon-containing layer increases as getting closer to the first epitaxial layer, and a distribution concentration of the group III atoms in the first epitaxial layer increases as getting closer to the first silicon-containing layer. A method of manufacturing a composite substrate is also provided in some embodiments of the present disclosure.

A stack including at least a semiconductor drift layer stacked on a single-crystal diamond substrate having a coalescence boundary, wherein the coalescence boundary of the single-crystal diamond substrate is a region that exhibits, in a Raman spectrum at a laser excitation wavelength of 785 nm, a full width at half maximum of a peak near 1332 cm.sup.−1 due to diamond that is observed to be broader than a full width at half maximum of the peak exhibited by a region different from the coalescence boundary, the coalescence boundary has a width of 200 μm or more, and the semiconductor drift layer is stacked on at least the coalescence boundary.

The present invention provides a silicon carbide composite wafer and a manufacturing method thereof. The silicon carbide composite wafer includes (a) a silicon carbide material and (b) a wafer substrate, and the upper surface of the wafer substrate is bonded to the lower surface of the silicon carbide material, wherein the lower surface of the silicon carbide material and/or the upper surface of the wafer substrate undergo a surface modification, thereby allowing the silicon carbide material to be bonded to the wafer substrate directly and firmly. The technical effects of the present invention include achieving strong bonding between the wafer and the substrate, reducing manufacturing process, increasing yield rate, and achieving high industrial applicability.

Disclosed are semiconductor structure embodiments of a semiconductor-on-insulator region on a bulk substrate. The semiconductor-on-insulator region includes an upper semiconductor layer above and physically separated from the substrate by insulator-containing cavities (e.g., by dielectric layer and/or a pocket of trapped air, of trapped gas, or under vacuum) and, optionally, by a lower semiconductor layer. Disclosed method embodiments include forming openings that extend vertically through the upper semiconductor layer, through a sacrificial semiconductor layer and, optionally, through a lower semiconductor layer to the substrate. Then, a selective isotropic etch process is performed to form cavities, which extend laterally off the sides of the openings into the sacrificial semiconductor layer. Depending upon the embodiments, different process steps are further performed to form plugs in at least the upper portions of the openings and insulators (including dielectric layers and/or a pocket of trapped air, of trapped gas or under vacuum) in the cavities.

Semiconductor device structures and methods for manufacturing the same are provided. The semiconductor device structure includes a substrate, a semiconductor layer on the substrate, and a patterned dielectric layer disposed on the substrate and covered by the semiconductor layer. The patterned dielectric layer is configured to prevent a constituent in the semiconductor layer from diffusing into the substrate. The semiconductor device structure further includes a first nitride semiconductor layer on the semiconductor layer and a second nitride semiconductor layer on the first nitride semiconductor layer. A band gap of the second nitride semiconductor layer is greater than a band gap of the first nitride semiconductor layer.

A III-nitride-based semiconductor device is provided. The III-nitride semiconductor device includes a silicon substrate having a surface with a periodic array of recesses formed therein. A discontinuous insulating layer is formed within each recess of the periodic array of recesses such that a portion of the silicon substrate surface between adjacent recesses is free from coverage of the discontinuous insulating layer. A first epitaxial III-nitride semiconductor layer is formed over the silicon substrate with the periodic array of recesses and discontinuous insulating layer formed thereon. A second III-nitride semiconductor layer is disposed over the first III-nitride semiconductor layer and has a bandgap greater than a bandgap of the first III-nitride semiconductor layer. At least one source and at least one drain are disposed over the second III-nitride semiconductor layer. A gate is also disposed over the second III-nitride semiconductor layer between the source and the drain.