A semiconductor heterostructure for an optoelectronic device is disclosed. The semiconductor heterostructure includes at least one stress control layer within a plurality of semiconductor layers used in the optoelectronic device. Each stress control layer includes stress control regions separated from adjacent stress control regions by a predetermined spacing. The stress control layer induces one of a tensile stress and a compressive stress in an adjacent semiconductor layer.

The present invention provides a method for producing a Group III nitride crystal, capable of producing a Group III nitride crystal in a large size with few defects and high quality. The method is a method for producing a Group III nitride crystal (13), including: a seed crystal selection step of selecting plural parts of a Group III nitride crystal layer (11) as seed crystals for generation and growth of Group III nitride crystals (13); a contact step of causing the surfaces of the seed crystals to be in contact with an alkali metal melt; a crystal growth step of causing a Group III element and nitrogen to react with each other under a nitrogen-containing atmosphere in the alkali metal melt to generate and grow the Group III nitride crystals (13), wherein the seed crystals are hexagonal crystals, in the seed crystal selection step, the seed crystals are arranged so that m-planes of the respective crystals grown from the seed crystals that are adjacent to each other do not substantially coincide with each other, and in the crystal growth step, the plural Group III nitride crystals (13) grown from the plural seed crystals by the growth of the Group III nitride crystals (13) are bound.

A III-nitride LED with simultaneous visible and ultraviolet (UV) emission, in which the visible emission is due to conventional InGaN active region mechanisms and the UV emission occurs due to Auger carrier injection into a UV light emitting region, such as impurity-doped AlGaN. The primary application for the III-nitride LED is general airborne pathogen inactivation to prevent the transmission of airborne-mediated pathogens while being safe for humans.

A method for producing a Group III nitride semiconductor comprising forming mesas on a main surface of a substrate, and growing Group III nitride semiconductor in a c-axis direction thereof, wherein the plane most parallel to the side surfaces of the mesas or the dents among the low-index planes of growing Group III nitride semiconductor is a m-plane (1-100), and when a projected vector obtained by orthogonally projecting a normal vector of the processed side surface to the main surface is defined as a lateral vector, an angle between the lateral vector and a projected vector obtained by orthogonally projecting a normal vector of the m-plane of the growing Group III nitride semiconductor to the main surface is 0.5° or more and 6° or less.

A light-emitting diode manufacturing method including the forming of three-dimensional semiconductor elements, extending along parallel axes, made of a III-V compound, each having a lower portion and a flared upper portion inscribed within a frustum of half apical angle α. The method further comprises, for each semiconductor element, the forming of an active area covering the top of the upper portion and the forming of at least one semiconductor layer of the III-V compound covering the active area by vapor deposition at a pressure lower than 10 mPa, by using a flux of the group-III element along a direction inclined by an angle θIII and a flux of the group-V element along a direction inclined by an angle θV with respect to the vertical axis, angles θIII and θV being smaller than angle α.

A method for manufacturing an indium gallium nitride quantum well is disclosed. The method includes providing a substrate in a process chamber, with the substrate including a gallium nitride layer. Having the process chamber reach a process vacuum. Providing a nitrogen molecular beam in plasma state, an indium molecular beam and an aluminum molecular beam into the process chamber simultaneously, controlling a flow rate ratio of the indium molecular beam to the aluminum molecular beam, and forming an indium aluminum nitride film on the gallium nitride layer, with the flow rate ratio being 0.6, 1.0, 1.29, 1.67 or 3.0. Forming an indium gallium nitride quantum well on the indium aluminum nitride film.

The electronic device comprises a substrate (1), at least one semiconductor wire element (2) formed by a nitride of a group III material and an electroconductive layer (3) interposed between the substrate (1) and said at least one semiconductor wire element (2). Said at least one semiconductor wire element (2) extends from said electroconductive layer (3), and the electroconductive layer (3) comprises a carbide of zirconium or a carbide of hafnium.

A gallium nitride (GaN) based light emitting diode (LED), wherein light is extracted through a nitrogen face (N-face) of the LED and a surface of the N-face is roughened into one or more hexagonal shaped cones. The roughened surface reduces light reflections occurring repeatedly inside the LED, and thus extracts more light out of the LED. The surface of the N-face is roughened by an anisotropic etching, which may comprise a dry etching or a photo-enhanced chemical (PEC) etching.

A growth method of aluminum gallium nitride is disclosed. The method includes the steps of: providing a substrate; forming a first aluminum gallium nitride layer on the substrate at a first temperature; and forming a second aluminum gallium nitride layer, on the first aluminum gallium nitride layer, at a second temperature. The first temperature is higher than the second temperature.

A solution for fabricating a semiconductor structure is provided. The semiconductor structure includes a plurality of semiconductor layers grown over a substrate using a set of epitaxial growth periods. During each epitaxial growth period, a first semiconductor layer having one of: a tensile stress or a compressive stress is grown followed by growth of a second semiconductor layer having the other of: the tensile stress or the compressive stress directly on the first semiconductor layer.