A method for making a semiconductor device may include forming a first single crystal silicon layer having a first percentage of silicon 28, and forming a superlattice above the first single crystal silicon layer. The superlattice may include a plurality of stacked groups of layers, with each group of layers comprising a plurality of stacked base silicon monolayers defining a base silicon portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base silicon portions. The method may further include forming a second single crystal silicon layer above the superlattice having a second percentage of silicon 28 higher than the first percentage of silicon 28.

Integrated circuit devices may include a fin-type active area, a semiconductor liner contacting a side wall of the fin-type active area and including a protrusion portion protruding outward from the fin-type active area in the vicinity of an edge of an upper surface of the fin-type active area, and an isolation layer spaced apart from the fin-type active area with the semiconductor liner therebetween. To manufacture the integrated circuit devices, a crystalline semiconductor layer covering the fin-type active area with a first thickness and an amorphous semiconductor layer covering the mask pattern with a second thickness may be formed, an extended crystalline semiconductor layer covering the mask pattern may be formed by crystalizing the amorphous semiconductor layer, and a semiconductor liner including a protrusion portion may be formed from the extended crystalline semiconductor layer and the crystalline semiconductor layer.

Epitaxially coated semiconductor wafers of monocrystalline silicon comprise a p.sup.+-doped substrate wafer and a p-doped epitaxial layer of monocrystalline silicon which covers an upper side face of the substrate wafer;

an oxygen concentration of the substrate wafer of not less than 5.3×10.sup.17 atoms/cm.sup.3 and not more than 6.0×10.sup.17 atoms/cm.sup.3;

a resistivity of the substrate wafer of not less than 5 mΩcm and not more than 10 mΩcm; and

the potential of the substrate wafer to form BMDs as a result of a heat treatment of the epitaxially coated semiconductor wafer, where a high density of BMDs has a maximum close to the surface of the substrate wafer.

A method of manufacturing a semiconductor nanowire semiconductor device is described. The method includes forming an amorphous channel material layer on a substrate, patterning the channel material layer to form semiconductor nanowires extending in a lateral direction on the substrate, and forming a cover layer covering an upper of the semiconductor nanowire. The cover layer and the nanowire are patterned to form a trench exposing a side section of an one end of the semiconductor nanowire and a catalyst material layer is formed in contact with a side surface of the semiconductor nanowire, and metal induced crystallization (MIC) by heat treatment is performed to crystallize the semiconductor nanowire in a length direction of the nanowire from the one end of the semiconductor nanowire in contact with the catalyst material.

A method for providing a film of one or more monolayers of transition metal dichalcogenides on a substrate is disclosed. The method includes providing a substrate; depositing at least one monolayer of the transition metal dichalcogenides on the substrate; and selectively removing superficial islands on top of the at least one monolayer by thermal etching.

Devices, and methods of forming such devices, having a material that is semimetal when in bulk but is a semiconductor in the devices are described. An example structure includes a substrate, a first source/drain contact region, a channel structure, a gate dielectric, a gate electrode, and a second source/drain contact region. The substrate has an upper surface. The channel structure is connected to and over the first source/drain contact region, and the channel structure is over the upper surface of the substrate. The channel structure has a sidewall that extends above the first source/drain contact region. The channel structure comprises a bismuth-containing semiconductor material. The gate dielectric is along the sidewall of the channel structure. The gate electrode is along the gate dielectric. The second source/drain contact region is connected to and over the channel structure.

A vertical nanowire semiconductor device manufactured by a method of manufacturing a vertical nanowire semiconductor device is provided. The vertical nanowire semiconductor device includes a substrate, a first conductive layer in a source or drain area formed above the substrate, a semiconductor nanowire of a channel area vertically upright with respect to the substrate on the first conductive layer, wherein a crystal structure thereof is grown in <111> orientation, a second conductive layer of a drain or source area provided on the top of the semiconductor nanowire, a metal layer on the second conductive layer, a NiSi.sub.2 contact layer between the second conductive layer and the metal layer, a gate surrounding the channel area of the vertical nanowire, and a gate insulating layer located between the channel area and the gate.

Epitaxially coated semiconductor wafers of monocrystalline silicon comprise a p.sup.+-doped substrate wafer and a p-doped epitaxial layer of monocrystalline silicon which covers an upper side face of the substrate wafer; an oxygen concentration of the substrate wafer of not less than 5.3×10.sup.17 atoms/cm.sup.3 and not more than 6.0×10.sup.17 atoms/cm.sup.3; a resistivity of the substrate wafer of not less than 5 mΩcm and not more than 10 mΩcm; and
the potential of the substrate wafer to form BMDs as a result of a heat treatment of the epitaxially coated semiconductor wafer, where a high density of BMDs has a maximum close to the surface of the substrate wafer.

A single crystal substrate is provided and is characterized in that the single crystal substrate has a foundation substrate provided with a plurality of first grooves, which include a first crystal face and a second crystal face opposed to the first crystal face in an inner face thereof, and the extending direction of which is a<110> direction, and a plurality of second grooves, the extending direction of which intersects with the first grooves, and in which the first grooves are formed in a displaced manner in a depth direction, and a transverse cross-sectional shape of the second groove is a shape in which straight lines are open at an opening angle less than 180°. Further, it is preferred that an angle formed by the first crystal face and the second crystal face is more than 70.6°.

A silicon carbide semiconductor device has a silicon carbide substrate, a first insulator, a first electrode, and a second electrode. The silicon carbide substrate includes a first impurity region, a second impurity region, a third impurity region, a first superjunction portion, a fourth impurity region, a fifth impurity region, a sixth impurity region, and a second superjunction portion. The first superjunction portion has a first region and a second region. The second superjunction portion has a third region and a fourth region. In a direction perpendicular to a second main surface, a bottom surface of a first trench is located between a second end surface and the second main surface and is located between a fourth end surface and the second main surface.