Abstract: Various embodiments may relate to a method for producing an optoelectronic component. The method may include increasing a refractive index of a substrate in at least one region at at least one predefined position in the substrate in such a way that the region having an increased refractive index extends as far as a surface of the substrate, and forming an electrode layer on or above the surface of the substrate at least partly above the region having an increased refractive index.

Abstract: Disclosed is an organic light-emitting, component which comprises a substrate, a first electrode on the substrate, a first organic functional layer stack on the first electrode, a charge carrier-generating layer stack on the first organic functional layer stack, a second organic functional layer stack on the charge carrier-generating layer stack, and a second electrode on the second organic functional layer stack. The charge carrier-generating layer stack comprises at least one hole-transporting layer, one electron-transporting layer and one intermediate layer, wherein the at least one intermediate layer comprises a naphthalocyanine derivative.

Abstract: Various embodiments may relate to an optoelectronic component device, including an optoelectronic component and a control device for driving the optoelectronic component. The optoelectronic component includes a first optically active structure and a second optically active structure. The first optically active structure is designed for emitting a first electromagnetic radiation and ages in accordance with a first ageing function during operation. The second optically active structure is designed for emitting a second electromagnetic radiation and ages in accordance with a second ageing function during operation. The optoelectronic component is formed in such a way that at least the first electromagnetic radiation is emitted in a first operating mode and at least the second electromagnetic radiation is emitted in a second operating mode.

Abstract: An organic light-emitting component includes a first light-emitting layer sequence, which is designed to emit light in a first wavelength range during the operation of the component. A second light-emitting layer sequence is designed to emit light in a second wavelength range during the operation of the component. A charge carrier generating layer sequence is designed to output charge carriers to the first light-emitting layer sequence and to the second light-emitting layer sequence during the operation of the component. The first wavelength range differs from the second wavelength range. The charge carrier generating layer sequence is arranged between the first light-emitting layer sequence and the second light-emitting layer sequence in a stacking direction of the organic light-emitting component.

Abstract: An organic light-emitting component has a substrate, a first electrode on the substrate, a first organic functional layer stack on the first electrode, a charge carrier generation layer stack on the first organic functional layer stack, a second organic functional layer stack on the charge carrier generation layer stack and a second electrode on the second organic functional layer stack. The charge carrier generation layer stack has at least one hole transport layer, one electron transport layer and one intermediate layer. The at least one intermediate layer includes a multinuclear phthalocyanine derivative.

Abstract: Various embodiments may relate to an optoelectronic component, including an optoelectronic structure, which is designed to provide a first electromagnetic radiation, and a measuring structure, which is designed to measure electromagnetic radiation, wherein the measuring structure has an optically active structure and at least one electro-optical structure. The optically active structure is optically coupled to the optoelectronic structure. The optically active structure is designed to absorb an electromagnetic radiation in such a way that the optically active structure produces a measured signal from the absorbed electromagnetic radiation. The absorbed electromagnetic radiation at least partially includes the first electromagnetic radiation and/or at least one second electromagnetic radiation of an external radiation source.

Abstract: An optoelectronic component includes a substrate, a first electrode, a second electrode, and at least one organic functional layer, which is arranged between the first electrode and the second electrode. The organic functional layer includes a matrix material, a first compound, and a second compound. The first compound interacts with the second compound, and the first compound and/or the second compound interacts with the matrix material. A conductivity of the organic functional layer is produced by the interactions.

Abstract: An optoelectronic device, comprising: a first organic functional layer structure; a second organic functional layer structure; and a charge generating layer structure between the first organic functional layer structure and the second organic functional layer structure, wherein the charge generating layer structure comprises: a first electron-conducting charge generating layer; wherein the first electron-conducting charge generating layer comprises or is formed from an intrinsically electron-conducting substance; a second electron-conducting charge generating layer; and an interlayer between first electron-conducting charge generating layer; and second electron-conducting charge generating layer; and wherein the interlayer comprises at least one phthalocyanine derivative.

Abstract: In at least one embodiment of the organic light-emitting diode (1), this comprises a mirror (3) and an organic layer sequence (4). The organic layer sequence (4) contains a first active layer (41) for producing first radiation and at least two second active layers (42, 43) for producing second radiation. The active layers (41, 42, 43) are arranged one above the other in a main direction (x) away from the mirror (3). A charge generation layer (45) is located in each case between two adjacent active layers (41, 42, 43). The second active layers (42, 43) each have the same at least two radiation active organic materials. The first active layer (41) has a radiation active organic material which is different therefrom.

Abstract: Various embodiments may relate to an optoelectronic device, including a first organic functional layer structure, a second organic functional layer structure, and a charge generating layer structure between the first organic functional layer structure and the second organic functional layer structure. The charge generating layer structure includes a first electron-conducting charge generating layer, a second electron-conducting charge generating layer, and an interlayer between the first electron-conducting charge generating layer and the second electron-conducting charge generating layer. The interlayer includes at least one phthalocyanine derivative. Various embodiments may further relate to a method for producing the optoelectronic device.

Abstract: Various embodiments may relate to a method for producing an optoelectronic component. The method may include increasing a refractive index of a substrate in at least one region at at least one predefined position in the substrate in such a way that the region having an increased refractive index extends as far as a surface of the substrate, and forming an electrode layer on or above the surface of the substrate at least partly above the region having an increased refractive index.

Abstract: An optoelectronic component may include a first organic functional layer structure, a second organic functional layer structure, and a charge generating layer structure between the first organic functional layer structure and the second organic functional layer structure. The charge generating layer structure includes a first electron-conducting charge generating layer, and a second electron-conducting charge generating layer. The second electron-conducting charge generating layer is formed from a single substance, and the substance of the first electron-conducting charge generating layer is a substance selected from the group of substances consisting of: HAT-CN, Cu(I)pFBz, NDP-2, NDP-9, Bi(III)pFBz, F16CuPc.

Abstract: An organic light-emitting component includes a first light-emitting layer sequence, which is designed to emit light in a first wavelength range during the operation of the component. A second light-emitting layer sequence which is designed to emit light in a second wavelength range during the operation of the component. A charge carrier generating layer sequence which is designed to output charge carriers to the first light-emitting layer sequence and to the second light-emitting layer sequence during the operation of the component. The first wavelength range differs from the second wavelength range. The charge carrier generating layer sequence is arranged between the first light-emitting layer sequence and the second light-emitting layer sequence in a stacking direction of the organic light-emitting component.

Abstract: In at least one embodiment of the organic light-emitting diode (1), this comprises a mirror (3) and an organic layer sequence (4). The organic layer sequence (4) contains a first active layer (41) for producing first radiation and at least two second active layers (42, 43) for producing second radiation. The active layers (41, 42, 43) are arranged one above the other in a main direction (x) away from the mirror (3). A charge generation layer (45) is located in each case between two adjacent active layers (41, 42, 43). The second active layers (42, 43) each have the same at least two radiation active organic materials. The first active layer (41) has a radiation active organic material which is different therefrom.

Abstract: An optoelectronic device, comprising: a first organic functional layer structure; a second organic functional layer structure; and a charge generating layer structure between the first organic functional layer structure and the second organic functional layer structure, wherein the charge generating layer structure comprises: a first electron-conducting charge generating layer; wherein the first electron-conducting charge generating layer comprises or is formed from an intrinsically electron-conducting substance; a second electron-conducting charge generating layer; and an interlayer between first electron-conducting charge generating layer; and second electron-conducting charge generating layer; and wherein the interlayer comprises at least one phthalocyanine derivative.

Abstract: Different embodiments of the optoelectronic component have an organic layer structure for isolating charge carriers of a first charge carrier type and charge carriers of a second charge carrier type. The organic layer structure comprises a copper complex which has at least one ligand with the chemical structure as per a formula (I). In this formula, E1 and E2 are each one of the following elements independently of one another: oxygen, sulphur or selenium. R is chosen from the group comprising: hydrogen or substituted or unsubstituted, branched, linear or cyclic hydrocarbons.

Abstract: A radiation-emitting arrangement comprises, in particular, a carrier element (1) having an at least partly non-transparent main surface (10) and arranged on the carrier element (1), an organic radiation-emitting component (2) having an organic layer sequence (23) with an active region between an at least partly transparent first electrode (21) and an at least partly transparent second electrode (22). The active region (29) is suitable for generating electromagnetic radiation (91, 93) in a switched-on operating state. The radiation-emitting arrangement has a radiation exit area (3) for emitting the electromagnetic radiation (92, 93) on that side of the organic radiation-emitting component (2) which faces away from the carrier element. (1) The at least partly non-transparent main surface (10) of the carrier element (1) is perceptible by an external observer through the radiation exit area (3) in a switched-off operating state of the organic radiation-emitting component (2).

Abstract: A radiation detector is disclosed with a detector arrangement, which has a plurality of detector elements, by means of which a detector signal is obtained during operation of the radiation detector, and with a control device, wherein the detector elements each have a spectral sensitivity distribution, and are suited for generating signals, at least one detector element comprises a compound semiconductor material, and this detector element is designed for detecting radiation in the visible spectral region, the radiation detector is designed such that the sensitivity distributions of the detector elements are used to form different spectral sensitivity channels of the radiation detector, a channel signal assigned to the respective sensitivity channel can be generated in these sensitivity channels using the detector elements, and the control device is designed such that the contributions of different channel signals to the detector signal of the radiation detector are differently controlled.

Abstract: The invention specifies a radiation detector for detecting radiation (8) according to a predefined spectral sensitivity distribution (9) that exhibits a maximum at a predefined wavelength ?0, comprising a semiconductor body (1) with an active region (5) serving to generate a detector signal and intended to receive radiation, in which according to one embodiment the active region (5) includes a plurality of functional layers (4a, 4b, 4c, 4d) that have different band gaps and/or thicknesses and are implemented such that they (4a, 4b, 4c, 4d) at least partially absorb radiation in a range of wavelengths greater than ?0. According to a further embodiment, disposed after the active region is a filter layer structure (70) comprising at least one filter layer (7, 7a, 7b, 7c), said filter layer structure determining the short-wave side (101) of the detector sensitivity (10) according to the predefined spectral sensitivity distribution (9) by absorbing wavelengths smaller than ?0.

Abstract: A radiation-emitting arrangement comprises, in particular, a carrier element (1) having an at least partly non-transparent main surface (10) and arranged on the carrier element (1), an organic radiation-emitting component (2) having an organic layer sequence (23) with an active region between an at least partly transparent first electrode (21) and an at least partly transparent second electrode (22). The active region (29) is suitable for generating electromagnetic radiation (91, 93) in a switched-on operating state. The radiation-emitting arrangement has a radiation exit area (3) for emitting the electromagnetic radiation (92, 93) on that side of the organic radiation-emitting component (2) which faces away from the carrier element. (1) The at least partly non-transparent main surface (10) of the carrier element (1) is perceptible by an external observer through the radiation exit area (3) in a switched-off operating state of the organic radiation-emitting component (2).