Abstract: The present invention provides methods for fabricating a composite substrate including a supporting substrate and a layer of a binary or ternary material having a crystal form that is non-cubic and semi-polar or non-polar. The methods comprise transferring the layer of a binary or ternary material from a donor substrate to a receiving substrate.

Abstract: A composite structure is disclosed that includes a support wafer and a layered structure on the support wafer. The layered structure includes at least one layer of a monocrystalline material and at least one layer of a dielectric material. In addition, the layered structure materials and the thickness of each layer are chosen such that the thermal impedance between ambient temperature and 600° K of the composite structure is a value that is no greater than about 1.3 times the thermal impedance of a monocrystalline bulk SiC wafer having the same dimensions as the composite structure. The composite structure provides sufficient heat dissipation properties for manufacturing optical, electronic, or optoelectronic components.

Abstract: A method of producing an optoelectronic substrate by detaching a thin layer from a semi-conducting nitride substrate and transferring it to an auxiliary substrate to provide at least one semi-conducting nitride layer thereon, metallizing at least a portion of the surface of the auxiliary substrate that includes the transferred nitride layer, bonding to a final substrate the metallized surface portion of the transferred nitrate layer of the auxiliary substrate, and removing the auxiliary substrate to provide an optoelectronic substrate comprising a semi-conducting nitride surface layer over a subjacent metallized portion and a supporting final substrate. Resultant optoelectronic substrates having low dislocation densities are also included.

Abstract: A method of forming an epitaxially grown layer by providing a support substrate that includes a region of weakness therein to define a support portion and a remainder portion on opposite sides of the region of weakness. The region of weakness comprises atomic species implanted in the support substrate to facilitate detachment of the support portion from the remainder portion. The method also includes epitaxially growing an epitaxially grown layer in association with the support portion.

Abstract: Improved fabrication processes for manufacturing GeOI type wafers are disclosed. In an implementation, a method for fabricating a germanium on insulator wafer includes providing a source substrate having a surface, at least a layer of germanium and a weakened area. The weakened area is located at a predetermined depth in the germanium layer of the source substrate and is generally parallel to the source substrate surface. The technique also includes providing a germanium oxynitride layer in or on the source substrate, bonding the source substrate surface to a handle substrate to form a source-handle structure, and detaching the source substrate from the source-handle structure at the weakened area of the source substrate to create the germanium on insulator wafer having, as a surface, a useful layer of germanium.

Abstract: A composite structure is disclosed that includes a support wafer and a layered structure on the support wafer. The layered structure includes at least one layer of a monocrystalline material and at least one layer of a dielectric material. In addition, the layered structure materials and the thickness of each layer are chosen such that the thermal impedance between ambient temperature and 600°°K of the composite structure is a value that is no greater than about 1.3 times the thermal impedance of a monocrystalline bulk SiC wafer having the same dimensions as the composite structure. The composite structure provides sufficient heat dissipation properties for manufacturing optical, electronic, or optoelectronic components.

Abstract: A method of forming an epitaxially grown layer, preferably by providing a region of weakness in a support substrate and transferring a nucleation portion to the support substrate by bonding. A remainder portion of the support substrate is detached at the region of weakness and an epitaxial layer is grown on the nucleation portion. The remainder portion is separated or otherwise removed from the support portion.

Abstract: A method for producing a support for epitaxy by forming a layer of insulating monocrystalline silicon carbide or insulating monocrystalline gallium nitride in a first substrate of conducting monocrystalline silicon carbide or gallium nitride. The method also includes transfer of the monocrystalline layer of silicon carbide or gallium nitride onto a second substrate formed from a polycrystalline ceramic material having thermal conductivity of 1.5 W.cm?1.K?1 or more. This method enables high performance electronic components to be produced cheaply, in particular for high frequency power applications.

Abstract: An efficient method of fabricating a high-quality heteroepitaxial microstructure having a smooth surface. The method includes detaching a layer from a base structure to provide a carrier substrate having a detached surface, and then forming a heteroepitaxial microstructure on the detached surface of the carrier substrate by depositing an epitaxial layer on the detached surface of a carrier substrate. Also included is a heteroepitaxial microstructure fabricated from such method.

Abstract: An efficient method of fabricating a high-quality microstructure having a smooth surface. The method includes detaching a layer from a base structure to provide a carrier substrate having a detached surface, and then forming a microstructure on the detached surface of the carrier substrate by depositing an epitaxial layer on the detached surface of a carrier substrate. Also included is a microstructure fabricated from such method.

Abstract: The invention relates to a method of re-forming a useful layer on a donor wafer after taking off a useful layer formed of a material chosen from among semiconductor materials. The donor wafer includes in succession a substrate and a taking-off structure, the taking-off structure includes the taken-off useful layer before taking-off. The method includes a removal of material involving a portion of the donor wafer on the side where the useful layer has been taken off. The material is removed by mechanical means so as to preserve a portion of the taking-off structure to form at least one other useful layer which can be taken off after re-forming, without adding additional material to the wafer.

Abstract: The invention relates to a recyclable donor wafer that includes a substrate and a formed layer thereon, wherein the formed layer has a thickness sufficient to provide (a) at least two useful layers for detachment therefrom and (b) additional material that can be removed to planarize exposed surfaces of the useful layers prior to detachment from the donor wafer.

Abstract: A method for fabricating an epitaxial substrate. The technique includes providing a crystalline or mono-crystalline base substrate, implanting atomic species into a front face of the base substrate to a controlled mean implantation depth to form a zone of weakness within the base substrate that defines a sub-layer, and growing a stiffening layer on a front face of the base substrate by using a thermal treatment in a first temperature range. The stiffening layer has a thickness sufficient to form an epitaxial substrate. In addition, the method includes detaching the stiffening layer and the sub-layer from the base substrate by using a thermal treatment in a second temperature range higher than the first temperature range. An epitaxial substrate and a remainder of the base substrate are obtained. The epitaxial substrate is suitable for use in growing high quality homoepitaxial or heteroepitaxial films thereon.

Abstract: A method for fabricating a carrier substrate. The technique includes providing a crystalline or mono-crystalline base substrate, growing a stiffening layer on a front face of the base substrate at a thickness sufficient to form a carrier substrate for subsequent processing, and detaching the stiffening layer from the base substrate to obtain the carrier substrate and a remainder of the base substrate. The carrier substrate is suitable for use in growing high quality homo-epitaxial or hetero-epitaxial films thereon.

Abstract: An efficient method of fabricating a high-quality microstructure having a smooth surface. The method includes detaching a layer from a base structure to provide a carrier substrate having a detached surface, and then forming a microstructure on the detached surface of the carrier substrate by depositing an epitaxial layer on the detached surface of a carrier substrate. Also included is a microstructure fabricated from such method.