Provided is a technique suitable for multilayering thin semiconductor elements via adhesive bonding while avoiding wafer damage in a method of manufacturing a semiconductor device, the method in which semiconductor elements are multilayered through laminating wafers in which the semiconductor elements are fabricated. The method of the present invention includes bonding and removing. In the bonding step, a back surface 1b side of a thinned wafer 1T in a reinforced wafer 1R having a laminated structure including a supporting substrate S, a temporary adhesive layer 2, and the thinned wafer 1T is bonded via an adhesive to an element forming surface 3a of a wafer 3. A temporary adhesive for forming the temporary adhesive layer 2 contains a polyvalent vinyl ether compound, a compound having two or more hydroxy groups or carboxy groups and thus capable of forming a polymer with the polyvalent vinyl ether compound, and a thermoplastic resin. The adhesive contains a polymerizable group-containing polyorganosilsesquioxane. In the removing step, a temporary adhesion by the temporary adhesive layer 2 between the supporting substrate S and the thinned wafer 1T is released to remove the supporting substrate S.

A method for obtaining a smooth surface of an epi-layer with epitaxial lateral overgrowth. The method does not use mis-cut orientations and does not suppress the occurrence of pyramidal hillocks, but instead embeds the pyramidal hillocks in the epi-layer. A growth restrict mask is used to limit the expansion of the pyramidal hillocks in a lateral direction. The surface of the epi-layer becomes extremely smooth due to the disappearance of the pyramidal hillocks.

Aspects include high resolution brain-electronic interfaces and related methods. Aspects include forming a semiconductor circuit on a substrate, depositing a tensile stress layer on the circuit, and separating the semiconductor circuit from a portion of the silicon substrate. Aspects also include removing the tensile stress layer from the semiconductor circuit and transferring the semiconductor circuit to a biocompatible film.

A semiconductor device includes a substrate, a channel layer, an insulating layer, source/drain contacts, a gate dielectric layer, and a gate electrode. The channel layer over the substrate and includes two dimensional (2D) material. The insulating layer is on the channel layer. The source/drain contacts are over the channel layer. The gate dielectric layer is over the insulating layer and the channel layer. The gate electrode is over the gate dielectric layer and between the source/drain contacts.

A device includes a layer including a first III-Nitride (III-N) material, a channel layer including a second III-N material, a release layer including nitrogen and a transition metal, where the release layer is between the first III-N material and the second III-N material. The device further includes a polarization layer including a third III-N material above the release layer, a gate structure above the polarization layer, a source structure and a drain structure on opposite sides of the gate structure where the source structure and the drain structure each include a fourth III-N material. The device further includes a source contact on the source structure and a drain contact on the drain structure.

Substrate-less vertical diode integrated circuit structures, and methods of fabricating substrate-less vertical diode integrated circuit structures, are described. For example, a substrate-less integrated circuit structure includes a semiconductor fin in a dielectric layer, the semiconductor fin having a top and a bottom, and the dielectric layer having a top surface and a bottom surface. A first epitaxial semiconductor structure is on the top of the semiconductor fin. A second epitaxial semiconductor structure is on the bottom of the semiconductor fin. A first conductive contact is on the first epitaxial semiconductor structure. A second conductive contact is on the second epitaxial semiconductor structure.

A device is disclosed which includes, in one illustrative example, an integrated circuit die having an active surface and a molded body extending around a perimeter of the die, the molded body having lips that are positioned above a portion of the active surface of the die. Another illustrative example includes an integrated circuit die having an active surface, a molded body extending around a perimeter of the die and a CTE buffer material formed around at least a portion of the perimeter of the die adjacent the active surface of the die, wherein the CTE buffer material is positioned between a portion of the die and a portion of the molded body and wherein the CTE buffer material has a coefficient of thermal expansion that is intermediate a coefficient of thermal expansion for the die and a coefficient of thermal expansion for the molded body.

A process can be used to allow processing of thin layers of a workpiece including dies. The workpiece can include a base substrate and a plurality of layers overlying the base substrate. The process can include forming a polymer support layer over the plurality of layers; thinning or removing the base substrate within a component region of the workpiece, wherein the component region includes an electronic device; and singulating the workpiece into a plurality of dies after thinning or removing the base substrate. In another aspect, an electronic device can be formed using such process. In an embodiment, the workpiece may have a size corresponding to a semiconductor wafer to allow wafer-level, as opposed to die-level, processing.

A method for manufacturing a wide band gap semiconductor device using a substrate of SiC wafer is disclosed. The method includes coating the substrate with a hard mask material, performing lithography to define patterned openings in the hard mask material of the substrate, etching the substrate to form patterned trenches from the defined patterned openings, removing the hard mask using a chemical process from the substrate, cleaning the substrate with the patterned trenches, performing epitaxy on the substrate to form a uniform single crystal layer over the patterned trenches to create a plurality of micro voids, kiss polishing the substrate, performing another epitaxy on the substrate using a fast epitaxial growth process to provide an active device epitaxial layer suitable to fabricate SiC devices, and after fabrication of the SiC devices, severing the plurality of micro voids to extract the SiC devices from the substrate of the SiC wafer.

Photovoltaics configured to be manufactured without epitaxial processes and methods for such manufacture are provided. Methods utilize bulk semiconducting crystal substrates, such as, for example, GaAs and InP such that epitaxy processes are not required. Nanowire etch and exfoliation processes are used allowing the manufacture of large numbers of photovoltaic cells per substrate wafer (e.g., greater than 100). Photovoltaic cells incorporate electron and hole selective contacts such that epitaxial heterojunctions are avoided during manufacture.