It is an object of the present invention to provide a semiconductor device having high heat dissipation performance. A semiconductor device includes: a diamond substrate having a recess in an upper surface thereof; a nitride semiconductor layer disposed within the recess in the upper surface of the diamond substrate; and an electrode disposed on the nitride semiconductor layer, wherein the nitride semiconductor layer and the electrode constitute a field-effect transistor, the diamond substrate has a source via hole extending through a thickness of the diamond substrate to expose the source electrode, and the semiconductor device further includes a via metal covering an inner wall of the source via hole and a lower surface of the diamond substrate.

Provided are a multilayer structure in which crystal defects due to stress concentration in a semiconductor layer caused by an insulator film are prevented and a semiconductor device using the multilayer structure, the multilayer structure and the semiconductor device that are particularly useful for power devices. A multilayer structure in which an insulator film is arranged on a part of a semiconductor film, wherein the semiconductor film has a corundum structure and contains a crystalline oxide semiconductor containing one or two or more metals selected from groups 9 and 13 of the periodic table, and wherein the insulator film has a taper angle of 20° or less.

A crystal growth method of the present disclosure includes: preparing a crystal growth-derived-layer forming substrate including (a) a substrate having a surface layer, (b) a mask pattern which is formed on the surface layer and which includes a plurality of strip bodies, and (c) a plurality of crystal growth-derived layers which are formed between and on the plurality of stripe bodies so as to have gaps therebetween above the plurality of strip bodies and which differ in lattice constant from the substrate having the surface layer; and growing semiconductor layers on the plurality of crystal growth-derived layers. The semiconductor layers are respectively grown on the plurality of crystal growth-derived layers formed so as to be separated from each other, and semiconductor layers on two adjacent ones of the plurality of crystal growth-derived layers are separated from each other.

A method of forming the fin structure that includes forming a replacement gate structure on a channel region of the at least one replacement fin structure; and forming an encapsulating dielectric encapsulating the replacement fin structure leaving a portion of the replacement gate structure exposed. The exposed portion of the replacement gate structure is etched to provide an opening through the encapsulating dielectric to the replacement fin structure. The replacement fin structure is etched selectively to the dielectric to provide a fin opening having a geometry dictated by the encapsulating dielectric. Functional fin structures of a second semiconductor material is epitaxially grown on the growth surface of the substrate substantially filling the fin opening.

The invention provides a quantum dot manufacturing method and related quantum dot semiconductor structure. The quantum dot semiconductor structure includes: a conductive ridge on a substrate; an insulative layer covering the substrate and the conductive ridge, wherein the insulative layer includes a top portion and two sidewalls over the conductive ridge; a plurality of quantum dots respectively embedded within a plurality of silicon dioxide spacer islands, which are adhered to the sidewalls of the insulative layer; and a plurality of conductive ledges adhered to the silicon dioxide spacer islands, wherein each of the conductive ledges is a portion of an electrode with alignment to the corresponding quantum dot.

A method of filling a recess according to one embodiment of the present disclosure comprises heating an amorphous semiconductor film without crystallizing the amorphous semiconductor film by radiating laser light to the amorphous semiconductor film embedded in the recess.

Semiconductor structures with reduced parasitic capacitance between interconnects and ground, for example, are described. In one case, a semiconductor structure includes a substrate and a low dielectric constant material region in the substrate. The low dielectric constant material region is positioned between a first device area in the semiconductor structure and a second device area in the semiconductor structure. The semiconductor structure also includes a III-nitride material layer over the substrate. The III-nitride material layer extends over the substrate in the first device area, over the low dielectric constant material region, and over the substrate in the second device area. The semiconductor structure can also include a first device formed in the III-nitride material layer in the first device area, a second device in the III-nitride material layer in the second device area, and an interconnect formed over the low dielectric constant material region. The interconnect can provide a continuous conductive path of metal from the first device area, over the low dielectric constant material region, and to the second device area.

A method for manufacturing a nitride semiconductor substrate, including: a step of preparing a base substrate; a step of forming a mask layer having a plurality of openings on the main surface of the base substrate; a first step of growing a first layer whose surface is composed only of inclined interfaces; and a second step of epitaxially growing a single crystal of a group III nitride semiconductor on the first layer, making the inclined interfaces disappear, and growing a second layer having a mirror surface, wherein in the first step, at least one valley and a plurality of tops are formed at an upper side of each of the plurality of openings of the mask layer by forming a plurality of concaves on a top surface of the single crystal and making the (0001) plane disappear.

The present application provides a method for manufacturing FDSOI devices. The method includes steps of: providing a semiconductor structure which comprises a silicon substrate, a buried oxide layer on the silicon substrate, a silicon-on-insulator layer on the buried oxide layer; and a hard mask layer on the silicon-on-insulator layer; performing spin coating of a photoresist on the hard mask layer to form a bulk silicon region; performing plasma anisotropic etching on the bulk silicon region to open a part of the buried oxide layer, and then performing isotropic etching, so that the silicon-on-insulator layer shrinks in the horizontal direction; performing plasma anisotropic etching to etch through the buried oxide layer to form a bulk silicon region trench; performing silicon epitaxial growth in the bulk silicon region trench. The silicon-on-insulator layer is still shrinks after the bulk silicon region trench is formed, as the result, there is no bump on the surface of the silicon-on-insulator layer, thus the process window becomes controllable.

A wafer includes a buried substrate; a first layer of silicon (100) disposed on the buried substrate that includes silicon sidewalls (111) at an angle to the buried substrate and that form a bottom of each of multiple U-shaped grooves; a second layer of patterned oxide disposed on the silicon (100) that provides vertical sidewalls of each U-shaped groove formed within the first and second layers; a third layer of a buffer covering the first layer and partially covering the second layer partway up the vertical sidewalls; and multiple gallium nitride (GaN)-based structures disposed within the multiple U-shaped grooves, the multiple GaN-based structures each including cubic gallium nitride (c-GaN) formed at merged growth fronts of hexagonal gallium nitride (h-GaN) that extend from the silicon sidewalls (111).