Abstract: A light-emitting component may include: an electrically active region, including: a first electrode; a second electrode; and an organic functional layer structure between the first electrode and the second electrode; and a thermotropic layer, which is arranged outside the electrically active region.

Abstract: The invention relates to an illuminant (23) and a socket (20) for a lamp (15). The features of the socket can be implemented also independently of the features of the illuminant (23). The socket has supply terminal areas on multiple sides of the socket housing such that the socket (20) can be selectively supplied with electricity and wired from different sides or also simultaneously from multiple sides. Independently of the number and the arrangement of the supply terminal areas (94), multiple electrical supply terminals (95) having the same polarity are provided on the socket (20). Said supply terminals (95) having the same polarity are electrically short-circuited by means of a shorting connector (116), in particular two identical shorting connectors (116) being arranged in the socket housing. Said socket (20) and illuminant (23) modularly achieve large total illumination surfaces in a lamp (15) and an appealing appearance in a very simple manner.

Abstract: An organic light-emitting component includes a substrate on which a functional layer stack is applied, the stack including a first electrode, an organic functional layer stack thereover including an organic light-emitting layer and a translucent second electrode thereover, and a translucent halogen-containing thin-film encapsulation arrangement over the translucent second electrode, wherein a translucent protective layer having a refractive index of more than 1.6 is arranged directly on the translucent second electrode between the translucent second electrode and the thin-film encapsulation arrangement.

Abstract: A dimming mirror device has a substrate having an electrochromic material that has a controllable transparency. At least one organic optoelectronic element, which has an organically functional layer stack, is arranged on the substrate. This element has at least one organic optoelectronic layer between two electrodes. The layer detects, in a first operational state of the mirror device, ambient light through the substrate such that the organic optoelectronic element acts, in the first operational state, as an element detecting organic light. The transparency of the substrate can be controlled in the first operational state in accordance with a measurement signal from the organic optoelectronic element.

Abstract: An encapsulation structure for an optoelectronic component may include: a barrier thin-film layer for protecting an optoelectronic component against chemical impurities; a cover layer applied above the barrier thin-film layer and serving for protecting the barrier thin-film layer against mechanical damage; and an intermediate layer applied on the barrier thin-film layer between barrier thin-film layer and cover layer and including a curable material designed such that when the non-cured intermediate layer is applied to the barrier thin-film layer, particle impurities at the surface of the barrier thin-film layer are enclosed by the intermediate layer and the applied intermediate layer has a substantially planar surface, and that after the intermediate layer has been cured, mechanical loads on the barrier thin-film layer as a result of particle impurities during the application of the cover layer are reduced by the intermediate layer.

Abstract: A method is specified for operating an organic optoelectronic component, which has at least one organic light-emitting element having an organic functional layer stack with at least one organic light-emitting layer between two electrodes and at least one organic light-emitting element having an organic light-detecting layer. These elements are arranged on a common substrate in laterally adjacent area regions. The at least one organic light-detecting element detects ambient light, which is incident onto the organic optoelectronic component. The intensity of the light emitted by the at least one organic light-emitting element is regulated depending on a signal of the at least one organic light-detecting element with a characteristic signal form.

Abstract: Various embodiments may relate to an optoelectronic component. The optoelectronic component may include a planar optically active structure and an electric circuit structure. The planar optically active structure is designed to receive and/or provide electromagnetic radiation. The electric circuit structure is designed such that it provides an output value. The output value is dependent on at least one operational parameter of the optically active structure.

Abstract: A method of producing an optoelectronic device includes A) providing a substrate, B) applying a first electrode to the substrate, C) applying a first organic layer stack to the first electrode, D) producing a charge-generating layer stack on the first organic layer stack, E) applying a second organic layer stack to the charge-generating layer stack, and F) applying a second electrode to the second organic layer stack, wherein step D) includes D1) applying a solution of a first metal oxide precursor to the first organic layer stack, D2) generating a first charge-generating layer comprising a first metal oxide, D3) applying a solution of a second metal oxide precursor to the first charge-generating layer, and D4) generating a second charge-generating layer comprising a second metal oxide.

Abstract: A light-emitting component may include: an electrically active region, including: a first electrode; a second electrode; and an organic functional layer structure between the first electrode and the second electrode; and a thermotropic layer, which is arranged outside the electrically active region.

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: The invention relates to an organic light-emitting part having a functional layer stack (10), which functional layer stack has a substrate (1), a first electrode (2) above the substrate, an organic functional layer stack (4) above the first electrode, having an organic light-emitting layer (5), and a second electrode (3) above the organic functional layer stack, wherein a layer (1, 2, 3) of the functional layer stack (10) forms a carrier layer (6) for a diffusion layer (7), wherein the diffusion layer (7) has at least one first and one second organic component (71, 72) having indices of refraction that differ from each other, wherein the first organic component (71) is hydrophobic and the second organic component (72) is hydrophilic, wherein the glass transition temperature of a mixture of the first organic component (71) and the second organic component (72); lies above the room temperature and wherein the first organic component (71) and the second organic component (72) are partially segregated in the diff

Abstract: An optoelectronic component includes an organic functional layer, having an active region that emits electromagnetic radiation, and a outcoupling element disposed in the beam path of the electromagnetic radiation emitted. The outcoupling element includes a matrix material and a separated phase disposed therein or a multitude of separated phases different than the matrix material. The refractive index of the separated phase is less than the refractive index of the matrix material. The separated phase in the matrix material causes scattering of the electromagnetic radiation is generated in the outcoupling element.

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: A method can be used for operating an organic light-emitting component. The organic light-emitting component has a first electrode and a second electrode, between which an organic functional layer stack with at least one organic light-emitting layer is arranged. The first and second electrodes and the organic functional layer stack have a large area. Electrical contact is made with the first electrode via at least two electrical connection elements in the peripheral regions, in which different electric voltages are applied to the at least two electrical connection elements and the different electric voltages vary over time. A lighting device for implementing the method is also specified.

Abstract: Various embodiments may relate to a method for processing an electronic component. The method includes applying a planar structure provided with predetermined separation locations to the electronic component, and removing a part of the applied planar structure, wherein removing includes separating the planar structure at the predetermined separation locations.

Abstract: A radiation-emitting device having an organic radiation-emitting functional layer and a radiation decoupling layer. The organic radiation-emitting functional layer emits a primary radiation; the radiation decoupling layer is disposed in the beam path of the primary radiation. On the side remote from the radiation-emitting functional layer the radiation decoupling layer comprises a microstructure having regularly disposed geometric structural elements; at least partial regions of the radiation decoupling layer contain regions which effect scattering of the primary radiation.

Abstract: Various embodiments relates to an organic light-emitting device, including at least one functional layer for generating electroluminescent radiation, an encapsulation structure formed on or over the at least one functional layer, and a heat conduction layer formed on or over the encapsulation structure. The heat conduction layer includes a matrix material and heat conducting particles embedded in the matrix material.

Abstract: Methods for protecting circuit device materials, optoelectronic devices, and caps using a reflowable getter are described. The methods, devices and caps provide advantages because they enable modification of the shape and activity of the getter after sealing of the device. Some embodiments of the invention provide a solid composition comprising a reactive material and a phase changing material. The combination of the reactive material and phase changing material is placed in the cavity of an electronic device. After sealing the device by conventional means (epoxy seal for example), the device is subjected to thermal or electromagnetic energy so that the phase changing material becomes liquid, and consequently: exposes the reactive material to the atmosphere of the cavity, distributes the getter more equally within the cavity, and provides enhanced protection of sensitive parts of the device by flowing onto and covering these parts, with a thin layer of material.

Abstract: An organic luminous means and an illumination device comprising such a luminous means are specified. An optical display apparatus, emergency lighting, motor vehicle interior lighting, an item of furniture, a construction material, a glazing and a display comprising such a luminous means and, respectively, comprising an illumination device having such a luminous means are furthermore specified.

Abstract: An organic optoelectronic component includes a substrate embodied in a light-transmissive fashion, an organic light-emitting element having an organic light-emitting layer between two electrodes, and an organic light-detecting element having an organic light-detecting layer. The organic light-emitting element and the organic light-detecting element are arranged on the substrate. Part of the light generated by the organic light-emitting element during operation enters into the substrate, emerges from the substrate and is detected by the organic light-detecting element.