A method for producing a -Ga.sub.2O.sub.3/-Ga.sub.2O.sub.3 multilayer body, wherein a -Ga.sub.2O.sub.3/-Ga.sub.2O.sub.3 multilayer body is obtained by mixing and melting Ga.sub.2O.sub.3, which serves as a solute, and PbO and Bi.sub.2O.sub.3, which serve as solvents, and subsequently bringing a -Ga.sub.2O.sub.3 substrate into direct contact with the thus-obtained melt, thereby growing a -Ga.sub.2O.sub.3 single crystal on the -Ga.sub.2O.sub.3 substrate by liquid-phase epitaxial growth.

There is provided a method for manufacturing a nitride crystal substrate, including: arranging a plurality of seed crystal substrates made of a nitride crystal in a planar appearance, so that their main surfaces are parallel to each other and their lateral surfaces are in contact with each other; growing a first crystal film using a vapor-phase growth method on a surface of the plurality of seed crystal substrates arranged in the planar appearance, and preparing a combined substrate formed by combining the adjacent seed crystal substrates each other by the first crystal film; growing a second crystal film using a liquid-phase growth method on a main surface of the combined substrate so as to be embedded in a groove that exists at a combined part of the seed crystal substrates, and preparing a substrate for crystal growth having a smoothened main surface; and growing a third crystal film using the vapor-phase growth method, on the smoothed main surface of the substrate for crystal growth.

A method of fabricating at least one single-crystal alloy semiconductor structure, comprising: forming at least one seed on a substrate for growth of at least one single-crystal alloy semiconductor structure, the at least one seed containing an alloying material; providing at least one structural form on the substrate which is crystallized to form the at least one single-crystal alloy semiconductor structure, the at least one structural form being formed of a host material and comprising a main body which extends from the at least one seed and a plurality of elements which are connected in spaced relation to the main body; heating the at least one structural form such that the material of the at least one structural form has a liquid state; and cooling the at least one structural form, such that the material of the at least one structural form nucleates at the least one seed and crystallizes as a single crystal to provide at least one single-crystal alloy semiconductor structure, with a growth front of the single crystal propagating in the main body of the respective structural form away from the respective seed; wherein the plurality of elements of each structural form provide reservoirs of the alloying material in liquid state, such that successive ones of the plurality of elements act to maintain, in liquid state, an available supply of the alloying material to the growth front of the single crystal in the main body of the respective structural form.

A method of growing an AlGaN semiconductor material utilizes an excess of Ga above the stoichiometric amount typically used. The excess Ga results in the formation of band structure potential fluctuations that improve the efficiency of radiative recombination and increase light generation of optoelectronic devices, in particular ultraviolet light emitting diodes, made using the method. Several improvements in UV LED design and performance are also provided for use together with the excess Ga growth method. Devices made with the method can be used for water purification, surface sterilization, communications, and data storage and retrieval.

A method for producing a Group III nitride semiconductor single crystal, includes forming a mask layer on an underlayer, to thereby form a seed crystal in which a portion of the underlayer is covered with the mask layer and in which the remaining portion of the underlayer is not covered with the mask layer, etching the remaining portion, and growing a Group III nitride semiconductor single crystal on the seed crystal.

A large Group III nitride crystal of high quality with few defects such as a distortion, a dislocation, and warping is produced by vapor phase epitaxy. A method for producing a Group III nitride crystal includes: a first Group III nitride crystal production process of producing a first Group III nitride crystal 1003 by liquid phase epitaxy; and a second Group III nitride crystal production process of producing a second Group III nitride crystal 1004 on the first crystal 1003 by vapor phase epitaxy. In the first Group III nitride crystal production process, the surfaces of seed crystals 1003a (preliminarily provided Group III nitride) are brought into contact with an alkali metal melt, a Group III element and nitrogen are cause to react with each other in a nitrogen-containing atmosphere in the alkali metal melt, and the Group III nitride crystals are bound together by growth of the Group III nitride crystals grown from the seed crystals 1003a to produce a first crystal 1003.

A large Group III nitride crystal of high quality with few defects such as a distortion, a dislocation, and warping is produced by vapor phase epitaxy. A method for producing a Group III nitride crystal includes: a first Group III nitride crystal production process of producing a first Group III nitride crystal 1003 by liquid phase epitaxy; and a second Group III nitride crystal production process of producing a second Group III nitride crystal 1004 on the first crystal 1003 by vapor phase epitaxy by causing a Group III element metal to react with an oxidizing agent and nitrogen-containing gas. In the first Group III nitride crystal production process, the surfaces of seed crystals 1003a (preliminarily provided Group III nitride) are brought into contact with an alkali metal melt, a Group III element and nitrogen are cause to react with each other in a nitrogen-containing atmosphere in the alkali metal melt, and the Group III nitride crystals are bound together by growth of the Group III nitride crystals grown from the seed crystals 1003a to produce a first crystal 1003.

A semiconductor device is provided. The semiconductor device includes a template layer disposed over a substrate and having a trench therein, a buffer structure disposed over a bottom surface of the trench and comprising a metal oxide, a single crystal semiconductor structure disposed within the trench and over the buffer structure and a gate structure disposed over a channel region of the single crystal semiconductor structure.

The present description concerns a method of manufacturing a device comprising at least one radio frequency component on a semiconductor substrate comprising: a) a laser anneal of a first thickness of the substrate on the upper surface side of the substrate; b) the forming of an insulating layer on the upper surface of the substrate; and c) the forming of said at least one radio frequency component on the insulating layer.

The present invention provides a method for producing a Group III nitride semiconductor single crystal having excellent crystallinity, and a method for producing a GaN substrate having excellent crystallinity, the method including controlling melting back. Specifically, a mask layer is formed on a GaN substrate serving as a growth substrate. Then, a plurality of trenches which penetrate the mask layer and reach the GaN substrate are formed through photolithography. The obtained seed crystal and raw materials of a single crystal are fed to a crucible and subjected to treatment under pressurized and high temperature conditions. Portions of the GaN substrate exposed to the trenches undergo melting back with a flux. Through dissolution of the GaN substrate, the dimensions of the trenches increase, to provide large trenches. The GaN layer is grown from the surface of the mask layer as a starting point.