A semiconductor device can define a plurality of points on the basis of an In ion concentration, a first dopant concentration, and a second dopant concentration, and identify each layer on the basis of a region between the points defined as above. The Mg concentration in a specific layer may increase along a specific direction and then decrease.

An epitaxial structure, a preparation method thereof, and a light-emitting diode (LED) are provided. The epitaxial structure includes a sapphire substrate, a GaN layer, a defect exposure layer, and a defect termination layer stacked in sequence.

A radiation-emitting semiconductor body having a semiconductor layer sequence includes an active region that generates radiation, an n-conducting region and a p-conducting region, wherein the active region is located between the n-conducting region and the p-conducting region, the p-conducting region includes a current expansion layer based on a phosphide compound semiconductor material, and the current expansion layer is doped with a first dopant incorporated at phosphorus lattice sites.

A lighting apparatus includes a light emitting diode, in which the light emitting diode includes an n-type nitride semiconductor layer, an active layer located on the n-type nitride semiconductor layer, and a p-type nitride semiconductor layer located on the active layer. The light emitting diode emits light that varies from yellow light to white light depending on an driving current.

An optoelectronic device including a substrate with first and second opposite surfaces; and electrical insulation side elements extending from the first surface to the second surface and defining, within the substrate, first semi-conductive or conductive portions which are electrically insulated from each other. The optoelectronic device also includes, for each first portion a first conductive contact pad on the second surface in contact with the first portion and a set of light-emitting diodes resting on the first surface and electrically connected to the first portion. The optoelectronic device also includes a conductive, at least partially transparent electrode layer covering all the light-emitting diodes; an insulating, at least partially transparent encapsulation layer covering the electrode layer; and at least one second conductive contact pad electrically connected to the electrode layer.

A composite substrate including a substrate, a buffer layer, and a strain release layer. The buffer layer is disposed on the substrate is provided. The strain release layer is disposed on the buffer layer, wherein the buffer layer is between the substrate and the strain release layer. A material of the strain release layer includes Al.sub.1-xGa.sub.xN, where 0≤x<0.15. The strain release layer is doped with silicon to release a compressive strain due to the buffer layer. A concentration of silicon doped in the strain release layer is greater than 10.sup.19 cm.sup.−3. A defect density of the strain release layer is less than or equal to 5×10.sup.9/cm.sup.2. A light-emitting diode is also provided.

A nitride semiconductor ultraviolet light-emitting element is provided. The element includes a light-emitting element structure part with an n-type layer, an active layer, and a p-type layer stacked vertically, which are made of AlGaN-based semiconductors with wurtzite structure. The n-type layer has an n-type AlGaN-based semiconductor, the active layer has well layers including an AlGaN based semiconductor, and the p-type layer has a p-type AlGaN-based semiconductor. Each semiconductor layer in the n-type and the active layers is an epitaxially grown layer having a surface on which multi-step terraces parallel to the (0001) plane are formed. The n-type layer has first Ga-rich regions which include n-type AlGaN regions in which an AlGaN composition ratio is an integer ratio of Al.sub.1Ga.sub.1N.sub.2. The well layer includes a second Ga-rich region, which includes an AlGaN region in which an AlGaN composition ratio is an integer ratio of Al.sub.1Ga.sub.2N.sub.3.

A radiation-emitting semiconductor component includes a semiconductor body having an active layer which emits electromagnetic radiation of a first wavelength λ.sub.1 in a main radiation direction, and having a luminescence conversion layer, which converts at least part of the emitted radiation into radiation of a second wavelength λ.sub.2, which is greater than the first wavelength λ.sub.1.

A light-emitting element includes, successively from a lower side to an upper side, a first n-side semiconductor layer, a first active layer, a first p-side semiconductor layer, a second n-side semiconductor layer, a second active layer, and a second p-side semiconductor layer, each made of a nitride semiconductor. The second n-side semiconductor layer contacts the first p-side semiconductor layer. The second n-side semiconductor layer includes, successively from a lower side to an upper side, a first layer including gallium, a second layer including aluminum and gallium, and a third layer including gallium and having a lower n-type impurity concentration than the first and second layers. A thickness of the first layer and a thickness of the second layer each is less than 50% of a thickness of the third layer.

The present invention generally relates to nanoscale wires and, in particular, to nanoscale wires with heterojunctions, such as tip-localized homo- or heterojunctions. In one aspect, the nanoscale wire may include a core, an inner shell surrounding the core, and an outer shell surrounding the inner shell. The outer shell may also contact the core, e.g., at an end portion of the nanoscale wire. In some cases, such nanoscale wires may be used as electrical devices. For example a p-n junction may be created where the inner shell is electrically insulating, and the core and the outer shell are p-doped and n-doped. Other aspects of the present invention generally relate to methods of making or using such nanoscale wires, devices, or kits including such nanoscale wires, or the like.