Abstract: The invention relates to a new High Electron Mobility Transistor (HEMT), made essentially of layers of Group XIII element(s) nitride(s). Contrary to currently available transistors of this type, the transistor according to the invention is produced on a homosubstrate made of gallium-containing nitride, has no nucleation layer and its buffer layer is remarkably thinner than in known HEMTs. Preferably, at least the buffer layer, being a part of the transistor according to the present invention, is produced by epitaxial methods and the direction of growth of said layer in an epitaxial process is essentially perpendicular to the direction of growth of the substrate. The invention relates also to a method of manufacturing of High Electron Mobility Transistor (HEMT).

Abstract: The invention relates to a substrate for epitaxy, especially for preparation of nitride semiconductor layers. Invention covers a bulk nitride mono-crystal characterized in that it is a mono-crystal of gallium nitride and its cross-section in a plane perpendicular to c-axis of hexagonal lattice of gallium nitride has a surface area greater than 100 mm2, it is more than 1,0 ?m thick and its C-plane surface dislocation density is less than 106/cm2, while its volume is sufficient to produce at least one further-processable non-polar A-plane or M-plane plate having a surface area at least 100 mm2. More generally, the present invention covers a bulk nitride mono-crystal which is characterized in that it is a mono-crystal of gallium-containing nitride and its cross-section in a plane perpendicular to c-axis of hexagonal lattice of gallium-containing nitride has a surface area greater than 100 mm2, it is more 1,0-?m thick and its surface dislocation density is less than 106/cm2.

Abstract: The invention relates to new improvements in a process for crystal growth in the environment of supercritical ammonia-containing solution, which are based on use of specific azide mineralizers and result in the improved bulk Group XIII element nitride monocrystals, in particular balk monocrystalline gallium-containing nitride, intended mainly for variety of nitride-based semiconductor products such as various opto-electronic devices. The invention further relates to a mineralizer used for supercritical ammonia-containing solution which comprises at least one compound selected from the group consisting of LiN3, NaN3, KN3, and CsN3.

Abstract: An apparatus includes an autoclave for preparing a supercritical solvent, a convection controller for establishing a convection flow, a dissolution zone where a feedstock is located above the convection controller and a crystallization zone where a seed is located below the convection controller are formed. A convection flow rate of the supercritical solution between the dissolution zone and the crystallization zone is determined by the degree of opening of the convection controller and the temperature difference between the dissolution zone and the crystallization zone. Accordingly, the supercritical solution, in which the nitride has a negative temperature coefficient of solubility, is supplied from the dissolution zone to the crystallization zone in which a seed is located through the convection controller so that nitride crystal is selectively grown on the seed by maintaining supersaturation of the supercritical solution with respect to the seed at a raised temperature.

Abstract: The present invention relates to a nitride semiconductor laser device provided with a window layer on a light-emitting end face of the resonator which comprises an active layer of nitride semiconductor between the n-type nitride semiconductor layers and the p-type nitride semiconductor layers, in which at least the radiation-emitting end face of said resonator is covered by said window layer comprising monocrystalline nitride of general formula AlxGa1?x?yINyN, where 0?x+y?1, 0?x?1 and 0?y<1, having a wider energy gap than that of the active layer and being formed at a low temperature so as not to damage said active layer. Formation of such a window layer improves significantly the performance of the nitride laser device according to the invention.

Abstract: The invention relates to a substrate for epitaxy, especially for preparation of nitride semiconductor layers. Invention covers a bulk nitride mono-crystal characterized in that it is a mono-crystal of gallium nitride and its cross-section in a plane perpendicular to c-axis of hexagonal lattice of gallium nitride has a surface area greater than 100 mm2, it is more than 1.0 ?m thick and its C-plane surface dislocation density is less than 106/cm2, while its volume is sufficient to produce at least one further-processable non-polar A-plane or M-plane plate having a surface area at least 100 mm2. More generally, the present invention covers a bulk nitride mono-crystal which is characterized in that it is a mono-crystal of gallium-containing nitride and its cross-section in a plane perpendicular to c-axis of hexagonal lattice of gallium-containing nitride has a surface area greater than 100 mm2, it is more 1.0 ?m thick and its surface dislocation density is less than 106/cm2.

Abstract: The invention relates to a substrate for epitaxy, especially for preparation of nitride semiconductor layers. Invention covers a bulk nitride mono-crystal characterized in that it is a mono-crystal of gallium nitride and its cross-section in a plane perpendicular to c-axis of hexagonal lattice of gallium nitride has a surface area greater than 100 mm2, it is more than 1.0 &mgr;m thick and its C-plane surface dislocation density is less than 106/cm2, while its volume is sufficient to produce at least one further-processable non-polar A-plane or M-plane plate having a surface area at least 100 mm2. More generally, the present invention covers a bulk nitride mono-crystal which is characterized in that it is a mono-crystal of gallium-containing nitride and its cross-section in a plane perpendicular to c-axis of hexagonal lattice of gallium-containing nitride has a surface area greater than 100 mm2, it is more 1.0 &mgr;m thick and its surface dislocation density is less than 106/cm2.