One object is to have stable electrical characteristics and high reliability and to manufacture a semiconductor device including a semi-conductive oxide film. Film formation is performed by a sputtering method using a target in which gallium oxide is added to a material that is easy to volatilize compared to gallium when the material is heated at 400° C. to 700° C. like zinc, and a formed film is heated at 400° C. to 700° C., whereby the added material is segregated in the vicinity of a surface of the film and the oxide is crystallized. Further, a semi-conductive oxide film is deposited thereover, whereby a semi-conductive oxide having a crystal which succeeds a crystal structure of the oxide that is crystallized by heat treatment is formed.

On-chip, doped semiconductor fuse regions compatible with FinFET CMOS fabrication are formed from the channel regions of selected fins. One or more fin dimensions are optionally reduced in selected channel regions of the fins following dummy gate removal, such as height and/or width. The channel regions from which the fuse regions are formed are doped to provide electrical conductivity, amorphized using ion implantation, and then annealed to form substantially polycrystalline fuse regions. Source/drain regions function as terminals for the fuse regions.

A semiconductor device includes a codoped layer, a channel layer, a barrier layer, and a gate electrode disposed in a trench extending through the barrier layer and reaching a middle point in the channel layer via a gate insulating film. On both sides of the gate electrode, a source electrode and a drain electrode are formed. On the source electrode side, an n-type semiconductor region is disposed to fix a potential and achieve a charge removing effect while, on the drain electrode side, a p-type semiconductor region is disposed to improve a drain breakdown voltage. By introducing hydrogen into a region of the codoped layer containing Mg as a p-type impurity in an amount larger than that of Si as an n-type impurity where the n-type semiconductor region is to be formed, it is possible to inactivate Mg and provide the n-type semiconductor region.

A method for making a semiconductor device may include forming a superlattice on a substrate comprising a plurality of stacked groups of layers, with each group of layers including a plurality of stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions. Moreover, forming at least one of the base semiconductor portions may include overgrowing the at least one base semiconductor portion and etching back the overgrown at least one base semiconductor portion.

A semiconductor substrate is a provided and an insulating layer is formed thereon. A cavity structure is formed above the insulating layer, including a lateral growth channel and a fin seed structure arranged in the lateral growth channel. The fin seed structure provides a seed surface for growing a fin structure. One or more first semiconductor structures of a first semiconductor material and one or more second semiconductor structures of a second, different, semiconductor material are grown sequentially in the growth channel from the seed surface in an alternating way. The first semiconductor structures provide a seed surface for the second semiconductor structures and the second semiconductor structures provide a seed surface for the first semiconductor structures. The second semiconductor structures are selectively etched, thereby forming the fin structure comprising a plurality of parallel fins of the first semiconductor structures. Corresponding semiconductor structures are also included.

A method for thickness measurement includes forming an implantation region in a semiconductor substrate. A semiconductor layer is formed on the implantation region of the semiconductor substrate. Modulated free carriers are generated in the implantation region of the semiconductor substrate. A probe beam is provided on the semiconductor layer and the implantation region of the semiconductor substrate with the modulated free carriers therein. The probe beam reflected from the semiconductor layer and the implantation region is detected to determine a thickness of the semiconductor layer.

Novel and useful quantum structures having a continuous well with control gates that control a local depletion region to form quantum dots. Local depleted well tunneling is used to control quantum operations to implement quantum computing circuits. Qubits are realized by modulating gate potential to control tunneling through local depleted region between two or more sections of the well. Complex structures with a higher number of qdots per continuous well and a larger number of wells are fabricated. Both planar and 3D FinFET semiconductor processes are used to build well to gate and well to well tunneling quantum structures. Combining a number of elementary quantum structure, a quantum computing machine is realized. An interface device provides an interface between classic circuitry and quantum circuitry by permitting tunneling of a single quantum particle from the classic side to the quantum side of the device. Detection interface devices detect the presence or absence of a particle destructively or nondestructively.

A silicon carbide semiconductor substrate includes: a base substrate that has a main surface having an outer diameter of not less than 100 mm and that is made of single-crystal silicon carbide; an epitaxial layer formed on the main surface; and a deformation suppression layer formed on a backside surface of the base substrate opposite to the main surface. In this way, the deformation suppression layer suppresses the substrate from being deformed (for example, warped during high-temperature treatment). This can reduce a risk of causing defects such as crack in the silicon carbide semiconductor substrate during the manufacturing process in performing a method for manufacturing a silicon carbide semiconductor device using the silicon carbide semiconductor substrate.

We describe a method for reducing bow in a composite wafer comprising a silicon wafer and a silicon carbide layer grown on the silicon wafer. The method includes applying nitrogen atoms during the growth process of the silicon carbide layer on the silicon wafer so as to generate a compressive stress within the composite wafer.

A method of in-situ transfer during fabrication of a component comprising a 2-dimensional crystalline thin film on a substrate is disclosed. In one embodiment, the method includes forming a layered structure comprising a polymer, a 2-dimensional crystalline thin film, a metal catalyst, and a substrate. The metal catalyst, being a growth medium for the two-dimensional crystalline thin film, is etched and removed by infiltrating liquid to enable the in-situ transfer of the two-dimensional crystalline thin film directly onto the underlying substrate.