Abstract: In an embodiment an optoelectronic semiconductor component includes a first semiconductor layer of an n-conductivity type, the first semiconductor layer being of AlxGa1-xN composition, with 0.3?x?0.95, a second semiconductor layer of a p-conductivity type, an active zone between the first semiconductor layer and the second semiconductor layer, the active zone including a quantum well structure and an intermediate layer between the first semiconductor layer and the active zone, wherein the intermediate layer includes a semiconductor material of AlyGa1-yN composition, with x*1.05?y?1, and wherein the intermediate layer is located directly adjacent to the active zone.

Abstract: A luminophore having the empirical formula A3M*OxF9-2x:Mn4+ where A may be or include Li, Na, Rb, K, Cs, or combinations thereof. M* may be or include Cr, Mo, W, or combinations thereof. x may be or include 0<x<4.5.

Abstract: A method of producing an optoelectronic component includes providing a semiconductor wafer with a functional semiconductor layer that has electronic control elements, and a growth layer; generating a plurality of recesses in the semiconductor wafer exposing the growth layer in places; and epitaxially growing a plurality of semiconductor layer stacks on the exposed growth layer, wherein a surface of the exposed growth layer is used as a growth surface for the semiconductor layer stacks, and the growth surface is inclined to a main extension plane of the semiconductor wafer.

Abstract: In an embodiment an optoelectronic component includes a first joining partner including an LED chip with a structured light-emitting surface and a compensation layer applied to the light-emitting surface, wherein the compensation layer has a surface facing away from the light-emitting surface and spaced apart from the light-emitting surface, and wherein the surface forms a first connecting surface, a second joining partner having a second connecting surface, the first and second connecting surfaces being arranged such that they face each other and a bonding layer made of a film of low-melting glass having a layer thickness of not more than 1 ?m, wherein the bonding layer bonds the first and second connecting surfaces together, wherein the structure of the light-emitting surface is embedded in the compensation layer, and wherein the first and second connecting surfaces are smooth such that their surface roughness, expressed as center-line roughness, is less than or equal to 50 nm.

Abstract: A structure comprising a nanoparticle converting electromagnetic radiation of a first wavelength into electromagnetic radiation of a second wavelength range, an interlayer at least partially surrounding the nanoparticle, and an encapsulation at least partially surrounding the interlayer is specified, wherein the interlayer comprises a plurality of first amphiphilic ligands and a plurality of second amphiphilic ligands and the first ligands and the second ligands are intercalated. Furthermore, an agglomerate comprising a plurality of structures, an optoelectronic device as well as methods for producing a structure and an agglomerate are disclosed.

Abstract: The invention relates to a lead frame assembly comprising a plurality of regularly arranged lead frames, each of which is suitable for electrically contacting components, comprises at least two lead frame elements distanced laterally by a recess and which are provided as electrical connections of different polarity, and has at least one anchoring element, which is suitable for anchoring a housing body of the component, the lead frame elements being thinned, flat regions of the lead frame, and the at least one anchoring element protrudes from a plane of the lead frame elements in the form of a pillar, and a plurality of connection elements, which in each case connects two lead frame elements of adjacent lead frames to one another, the two connected lead frame elements being provided as terminals of different polarity.

Abstract: Devices, methods, and systems for detecting proximity. A first light emitter emits light for a first time period while a light detector is not sensing. A second light emitter emits light for a second time period while the light detector is sensing. In some implementations, the first light emitter directly illuminates the light detector during the first time period, whereas the second light emitter is obstructed from directly illuminating the light detector during the second time period. In some implementations, the first light emitter is obstructed from illuminating a display during the first time period, and the second light emitter is obstructed from directly illuminating the light detector during the second time period. In some implementations, the first light emitter emits the light during the first time period such that the light detector maintains a linear responsivity during the second time period.

Abstract: A radiation-emitting device may include a radiation-emitting semiconductor chip configured to emit electromagnetic radiation of a first wavelength range from a radiation exit surface, a first phosphor configured to convert electromagnetic radiation of the first wavelength range into electromagnetic radiation of a second wavelength range. The second wavelength range may be or include infrared light. The device may further include an up-converting phosphor configured to convert infrared light of the second wavelength range into visible light.

Abstract: In an embodiment a method includes providing a growth substrate with a plurality of semiconductor bodies for the semiconductor devices, wherein each semiconductor body comprises electrical contact structures and a separation layer arranged towards the growth substrate, arranging a rigid first auxiliary carrier on a side of the semiconductor bodies facing away from the growth substrate, wherein the first auxiliary carrier comprises a first detachment layer, detaching the growth substrate by laser radiation, wherein the laser radiation is absorbed in the separation layer, arranging a rigid second auxiliary carrier on a side of the semiconductor bodies facing away from the first auxiliary carrier, wherein the second auxiliary carrier comprise a second detachment layer, detaching the first auxiliary carrier by laser radiation, wherein the laser radiation is absorbed in the first detachment layer and the separation layer still extending continuously over the growth substrate while detaching and mechanically and el

Abstract: In an embodiment an adhesive transfer stamp for transferring semiconductor chips includes a volume region including an electrically insulating material, at least one adhesive surface configured to receive a semiconductor chip and an electrically conductive element configured to electrically conductively connected to a ground conductor during operation and to dissipate electrical charges from the semiconductor chip to the ground conductor, wherein the volume region is embodied as a solid body, and wherein the volume region has at least one stepped structure.

Abstract: Semiconductor structures having a nanocrystalline core and corresponding nanocrystalline shell and insulator coating, wherein the semiconductor structure includes an anisotropic nanocrystalline core composed of a first semiconductor material, and an anisotropic nanocrystalline shell composed of a second, different, semiconductor material surrounding the anisotropic nanocrystalline core. The anisotropic nanocrystalline core and the anisotropic nanocrystalline shell form a quantum dot. An insulator layer encapsulates the nanocrystalline shell and anisotropic nanocrystalline core.

Abstract: The invention relates to a light-emitting component comprising a light-emitting semiconductor chip, a transparent conductive layer, and at least two electrical connection points, wherein the transparent conductive layer covers the light-emitting semiconductor chip at least in places, and the electrical connection points are arranged on a side of the light-emitting semiconductor chip facing away from the transparent conductive layer.

Abstract: In an embodiment an optoelectronic semiconductor chip includes a semiconductor layer sequence with a first layer, a second layer and an active layer arranged between the first layer and the second layer, the semiconductor layer sequence having at least one injection region, wherein the first layer includes a first conductivity type, wherein the second layer includes a second conductivity type, wherein the semiconductor layer sequence includes the first conductivity type within the entire injection region, wherein the injection region, starting from the first layer, at least partially penetrates the active layer, wherein side surfaces of the semiconductor layer sequence are formed at least in places by the injection region, and wherein the injection region is configured to inject charge carriers directly into the active layer.

Abstract: In an embodiment a method for structuring a semiconductor surface includes providing the semiconductor surface, wherein the semiconductor surface is part of a GaN-semiconductor layer, irradiating the semiconductor surface with an electron beam in order to produce an irradiated section and anisotropic wet-chemical etching of the semiconductor surface, wherein an etching rate in the irradiated section is less than that in an unirradiated section of the semiconductor surface, and wherein no etching mask is applied to the semiconductor surface before anisotropic wet-chemical etching.

Abstract: In an embodiment a method for producing a plurality of radiation-emitting devices includes providing a plurality of semiconductor chips on a main surface of a carrier, each semiconductor chip for emitting electromagnetic radiation from a radiation exit surface, arranging a lens mold with a plurality of cavities over the carrier, introducing a liquid mold material into the cavities of the lens mold and curing the liquid mold material such that a plurality of molded lenses is generated, wherein the molded lenses directly adjoin the main surface of the carrier, wherein regions of an outer surface of the molded lenses directly adjacent to the main surface of the carrier are free of planar areas, and wherein the carrier includes a plurality of carrier elements, the carrier elements having a first recess in a main surface extending from a side face of the carrier element.

Abstract: The invention relates to a light emitter unit having at least one VCSEL chip, which light emitter unit comprises: a light exit surface, via which light produced by the VCSEL chip and radiated perpendicularly to the chip plane is emitted into the surroundings; and contacts for supplying the electrical energy required for the production of the light by the VCSEL chip. The described technical solution is characterized in that at least one lateral surface of the VCSEL chip arranged perpendicularly to the chip plane is touched and covered, at least in parts, by a cover element.

Abstract: An optoelectronic semiconductor device may include a carrier having a roughened first main surface and optoelectronic semiconductor chips arranged over the roughened first main surface. The combined surface area of the optoelectronic semiconductor chips is smaller than the surface area of the carrier, and a part of the roughened first main surface is arranged between adjacent optoelectronic semiconductor chips.

Abstract: In an embodiment an optical measuring arrangement includes a tube section-shaped hollow body having a central axis extending from a first end face to an opposite second end face of the hollow body, wherein a spiral-shaped hollow light guide is formed in an inner surface of the hollow body by the inner surface being formed at least partially from a light-reflecting material and being formed as a hollow spiral winding around the central axis with a hollow cross section open toward the central axis, a light source arranged at a first spiral end and lying on the first end face of the hollow body, the light source configured to emit a light beam into the hollow spiral so that the light beam is tangentially to its turns and, after a plurality of reflections inside the hollow spiral, emerges from a second spiral end lying on the second end face of the hollow body and a light detector arranged at the second spiral end, the light detector configured to detect the emerging light beam and to output an electronic measure

Abstract: In an embodiment a method includes arranging a first semiconductor wafer above a carrier, wherein the first semiconductor wafer includes a plurality of first semiconductor optoelectronic components, separating a plurality of the first components from the first semiconductor wafer by laser radiation so that the first components fall onto the carrier and attaching the first components separated from the first semiconductor wafer to the carrier, wherein regions of the first semiconductor wafer between adjacent first components are thinned and the first components are covered with a passivation layer before the first components are separated from the first semiconductor wafer.

Abstract: In an embodiment a component includes a semiconductor chip, a connection member and a carrier, wherein the semiconductor chip is mechanically and electrically connected to the carrier via the connection member, wherein the connection member includes a contiguous metallic connecting layer and a plurality of metallic through-vias extending vertically through the connecting layer and being laterally spaced from the connecting layer by insulating regions, wherein the insulating regions are filled with a gaseous medium and are hermetically sealed, and wherein the gaseous medium contains an insulating gas having a higher breakdown field strength compared to nitrogen, or wherein a gas pressure is less than 1 mbar in the hermetically sealed insulating regions.