Abstract: An optoelectronic component includes a housing, wherein a cavity is formed on an upper side of the housing, which is delimited by a wall, the housing has an empty space, the wall is arranged between the cavity and the empty space, the housing has a surface, the empty space is arranged between the surface of the housing and the wall, the wall and the surface are arranged at least partially parallel to each other, the wall includes an optically transparent material, and the wall has a wall thickness of 1 ?m to 100 ?m.

Abstract: An electronic component, an optoelectronic component, and a component arrangement are disclosed. In an embodiment the electronic component includes an electronic semiconductor chip and a molded body, wherein the molded body covers at least one side face of the electronic semiconductor chip, wherein a surface of the electronic semiconductor chip is at least partly not covered by the molded body, wherein the molded body includes a first side face with a peg, and wherein the molded body includes a second side face with a groove matching the peg.

Abstract: An optoelectronic component includes a carrier, wherein a first optoelectronic semiconductor chip and a second optoelectronic semiconductor chip are arranged above a top side of the carrier, the optoelectronic semiconductor chips each include a top side, an underside situated opposite the top side, and side faces extending between the top side and the underside, the undersides of the optoelectronic semiconductor chips face the top side of the carrier, a first potting material is arranged above the top side of the carrier, the first potting material covering parts of the side faces of the first optoelectronic semiconductor chip, and a second potting material is arranged above the top side of the carrier, and the second potting material covering the first potting material.

Abstract: An electromagnetic radiation-emitting assembly is disclosed. In an embodiment the assembly includes an electromagnetic radiation-emitting component arranged above a carrier, the electromagnetic radiation-emitting component including a first side facing away from the carrier, a second side facing the carrier, and at least one side wall connecting the first side and the second side of the electromagnetic radiation-emitting component to one another, an encapsulating body, into which the electromagnetic radiation-emitting component is embedded, which adjoins the first side and the side wall of the electromagnetic radiation-emitting component, a potting material at least partly surrounding the encapsulating body and a reflector body at least partly surrounding the potting material.

Abstract: The invention relates to a method for producing a plurality of conversion elements (6) comprising the following steps: providing a substrate (1); applying a first mask layer (4) to the substrate (1), the first mask layer (4) being structured with through-holes (3) which completely penetrate the first mask layer (4); applying a conversion material (5) at least into the through-holes (3); and singulating the conversion elements (6) so as to produce a plurality of individual conversion elements (6). The invention also relates to two other methods, to a conversion element (6), and to an optoelectronic component.

Abstract: An electronic component, an optoelectronic component, a component arrangement, and a method for producing an electronic component are disclosed. In an embodiment, the method includes forming a sacrificial structure on a top side of a carrier by a photolithographic process from a photoresist layer, arranging an electronic semiconductor chip on the carrier after exposing the photoresist layer, molding a molded body around the sacrificial structure and around the electronic semiconductor chip such that a surface of the electronic semiconductor chip is at least partly not covered by the molded body, detaching the molded body from the carrier and removing the sacrificial structure, wherein removing the sacrificial structure results in a cutout being formed in the molded body.

Abstract: An optoelectronic component includes a housing having a cavity in which an optoelectronic semiconductor chip having an emission face that emits light rays and a transparent potting material are arranged, wherein the cavity includes at least one side wall at least partly reflecting light rays incident on the side wall and reflectivity of which decreases as an operating period of the component increases, conversion particles are embedded into the potting material, which conversion particles convert light rays having a first wavelength incident on the conversion particles into light rays having a second wavelength, and scattering particles are embedded into the potting material, which scattering particles scatter light rays incident on the scattering particles and the scattering capability of which scattering particles increases as the operating period increases.

Abstract: An optoelectronic component includes a housing having a cavity in which an optoelectronic semiconductor chip having an emission face that emits light rays and a transparent potting material are arranged, wherein the cavity includes at least one side wall at least partly reflecting light rays incident on the side wall and reflectivity of which decreases as an operating period of the component increases, conversion particles are embedded into the potting material, which conversion particles convert light rays having a first wavelength incident on the conversion particles into light rays having a second wavelength, and scattering particles are embedded into the potting material, which scattering particles scatter light rays incident on the scattering particles and the scattering capability of which scattering particles increases as the operating period increases.

Abstract: An electronic component, an optoelectronic component, a component arrangement, and a method for producing an electronic component are disclosed. In an embodiment, the method includes forming a sacrificial structure on a top side of a carrier by a photolithographic process from a photoresist layer, arranging an electronic semiconductor chip on the carrier after exposing the photoresist layer, molding a molded body around the sacrificial structure and around the electronic semiconductor chip such that a surface of the electronic semiconductor chip is at least partly not covered by the molded body, detaching the molded body from the carrier and removing the sacrificial structure, wherein removing the sacrificial structure results in a cutout being formed in the molded body.

Abstract: An optoelectronic component includes a housing, wherein a cavity is formed on an upper side of the housing, which is delimited by a wall, the housing has an empty space, the wall is arranged between the cavity and the empty space, the housing has a surface, the empty space is arranged between the surface of the housing and the wall, the wall and the surface are arranged at least partially parallel to each other, the wall includes an optically transparent material, and the wall has a wall thickness of 1 ?m to 100 ?m.

Abstract: A varistor paste includes a matrix material and particles embedded into the matrix material, wherein the matrix material without embedded particles has a viscosity of less than 0.8 Pa·s, and the embedded particles include varistor particles. An optoelectronic component includes an optoelectronic semiconductor chip and a varistor element connected in parallel with the optoelectronic semiconductor chip, wherein the varistor element includes a matrix material and particles embedded into the matrix material, the embedded particles include varistor particles, and the matrix material has a glass transition temperature of more than 130° C. A method of producing a varistor paste includes providing a matrix material having a viscosity of less than 0.8 Pa·s; and embedding particles into the matrix material to form a varistor paste, wherein the embedded particles include varistor particles.

Abstract: An optoelectronic assembly includes at least one first component that emits first electromagnetic radiation and at least one first photosensitive component that controls the first component. The first photosensitive component connects in parallel to the first component and has a first radiation-sensitive region in a beam path of the first electromagnetic radiation.

Abstract: A radiation-emitting semiconductor component including a volume-emitting semiconductor chip including a first main surface and a second main surface opposite the first main surface, a first reflective element arranged at the first main surface and reflects electromagnetic radiation emerging through the first main surface during operation of the semiconductor chip back to the first main surface, a second reflective element arranged at the second main surface and reflects electromagnetic radiation emerging through the second main surface during operation of the semiconductor chip back to the second main surface, and at least one radiation exit surface through which electromagnetic radiation generated during the operation of the semiconductor component emerges from the semiconductor component, wherein the at least one radiation exit surface runs transversely with respect to the first main surface and the second main surface of the semiconductor chip.