Abstract: The present invention relates to a method for controlling a condition of a plant.

Abstract: The present invention refers to a method for modulating a condition of a biological cell.

Abstract: The invention relates to the field of controlling the growth of an organism, or a plurality of organisms, such as particularly one more plants. Specifically, the invention is directed to a modulating system for modulating light to which an organism is to be exposed.

Abstract: The present invention relates to a phosphor and a composition.

Abstract: The present invention relates to a composition comprising at least one phosphor.

Abstract: The present invention relates to a photosensitive composition comprising at least one nanosized fluorescent material and polysiloxane, to a color conversion film, and to a use of the color conversion film in an optical device. The invention further relates to an optical device comprising the color conversion film and a method for preparing the color conversion film and the optical device.

Abstract: The present invention relates to a composition comprising a fluorescent material and a matrix material, a color conversion sheet and a light emitting diode device. The present invention further relates to the use of the composition in a color conversion sheet fabrication process, to the use of the color conversion sheet in optical devices or for agriculture purposes, and to the use of the fluorescent material and the matrix material in light emitting diode devices. Additionally, the invention relates to an optical device comprising the color conversion sheet and to a method for preparing the color conversion sheet and the optical device.

Abstract: The present invention relates to a luminescent particle, ink formulation, polymer composition, optical device and a preparation thereof. The invention further relates to use of a luminescent particle in a medium or biological imaging.

Abstract: The present invention relates to a photosensitive composition comprising at least one nanosized fluorescent material and polysiloxane, to a color conversion film, and to a use of the color conversion film in an optical device. The invention further relates to an optical device comprising the color conversion film and a method for preparing the color conversion film and the optical device.

Abstract: The present invention relates to polarized light emissive films, and to a preparation thereof. The invention also relates to use of the polarized light emissive film in an optical device. The invention further relates to an optical device and to a preparation thereof. The invention further relates to a mixture comprising a plural of inorganic fluorescent semiconductor quantum rods, and to use of the mixture for preparing the polarized light emissive film. The present invention furthermore relates to a polarized light emissive nanofiber, to use and to a preparation thereof.

Abstract: An integrated circuit having a semiconductor substrate with a barrier layer is disclosed. The arrangement includes a semiconductor substrate and a metallic element. A carbon-based barrier layer is disposed between the semiconductor substrate and the metallic element.

Abstract: A substrate has at least one feedthrough with at least one channel from a first main surface of the substrate to a second main surface of the substrate. The at least one channel is closed off with a first material. The at least one closed-off channel is filled with an electrically conductive second material.

Abstract: A substrate with first and second main surfaces includes at least one channel extending from the first main surface to the second main surface. The at least one channel includes a first cross-sectional area at a first location and a second cross-sectional area at a second location. An electrically conductive first material is disposed in the at least one channel.

Abstract: An integrated circuit having a semiconductor substrate with a barrier layer is disclosed. The arrangement includes a semiconductor substrate and a metallic element. A carbon-based barrier layer is disposed between the semiconductor substrate and the metallic element.

Abstract: An integrated circuit having a semiconductor substrate with a barrier layer is disclosed. The arrangement includes a semiconductor substrate and a metallic element. A carbon-based barrier layer is disposed between the semiconductor substrate and the metallic element.

Abstract: An integrated circuit having a semiconductor substrate with a barrier layer is disclosed. The arrangement includes a semiconductor substrate and a metallic element. A carbon-based barrier layer is disposed between the semiconductor substrate and the metallic element.

Abstract: A substrate with first and second main surfaces includes at least one channel extending from the first main surface to the second main surface. The at least one channel includes a first cross-sectional area at a first location and a second cross-sectional area at a second location. An electrically conductive first material is disposed in the at least one channel.

Abstract: Device having a flat macroporous support material made of silicon and having surfaces, a plurality of pores each having a diameter in a range of from 500 nm to 100 ?m distributed over at least one surface region of the support material and extending from one surface through to the opposite surface of the support material, at least one region having one or more pores with SiO2 pore walls, and a frame of walls with a silicon core surrounding the at least one region and arranged essentially parallel to longitudinal axes of the pores and open towards the surfaces, wherein the silicon core merges into silicon dioxide over a cross section towards an outer side of the walls forming the frame.

Abstract: A device and method for producing a “biochip base module” for detecting biochemical reactions for the study of enzymatic reactions, nucleic acid hybridizations, protein-protein interactions and other binding reactions in the field of genome, proteome, or active-agent research. A flat macroporous support material having a multiplicity of 500 nm to 100 ?m diameter pores distributed over at least one surface region and extending from one surface through to the opposite surface of the support material. The device has two or more regions having pores with SiO2 pore walls. These regions are each surrounded by a frame or box of walls with a silicon core arranged parallel to the longitudinal axes of the pores and is open towards the surfaces. The silicon core merges into silicon dioxide over the cross section towards the outer side of the walls forming the frame, and each individual frame is spatially isolated from the frames surrounding it.

Abstract: A method for carrying out an amplification of nucleic acids in pores of a two-dimensionally designed macroporous support material according to one embodiment includes the step of providing a predetermined part of a reaction mixture necessary for the amplification of a nucleic acid in pores of the support material. A device for carrying out the amplification of nucleic acids according to one embodiment includes a two-dimensionally designed macroporous support material having a multiplicity of pores, wherein a predetermined part of a reaction mixture for carrying out an amplification of nucleic acids is provided in the pores.