Abstract: A composite substrate (1) comprising a substrate body (2) and a utility layer (31) fixed on the substrate body (2). A planarization layer (4) is arranged between the utility layer (31) and the substrate body (2). A method for producing a composite substrate (1) applies a planarization layer (4) on a provided utility substrate (3). The utility substrate (3) is fixed on a substrate body (2) for the composite substrate (1). The utility substrate (3) is subsequently separated, wherein a utility layer (31) of the utility substrate (3) remains for the composite substrate (1) on the substrate body (2).

Abstract: An optical semiconductor device with a multiple quantum well structure, in which well layers and barrier layers comprising various types of semiconductor layers are alternately layered, in which device well layers (6a) of a first composition based on a nitride semiconductor material with a first electron energy and barrier layers (6b) of a second composition of a nitride semiconductor material with electron energy which is higher in comparison with the first electron energy are provided, followed, seen in the direction of growth, by a radiation-active quantum well layer (6c), for which the essentially non-radiating well layers (6a) and the barrier layers (6b) arranged in front form a superlattice.

Abstract: An optoelectronic semiconductor chip comprises the following sequence of regions in a growth direction (c) of the semiconductor chip (20): a p-doped barrier layer (1) for an active region (2), the active region (2), which is suitable for generating electromagnetic radiation, the active region being based on a hexagonal compound semiconductor, and an n-doped barrier layer (3) for the active region (2). Also disclosed are a component comprising such a semiconductor chip, and a method for producing such a semiconductor chip.

Abstract: A semiconductor chip (1) comprises a semiconductor body (2) having a semiconductor layer sequence having an active region (23) provided for generating radiation. A contact (4) is arranged on the semiconductor body (2). An injection barrier (5) is formed between the contact (4) and the active region (23). A method for producing a semiconductor chip is also disclosed.

Abstract: An optical arrangement comprising at least one first light-emitting element (LE1) and at least one second light-emitting element (LE2), and at least one light addition device (1) arranged in such a way that the light from the first and the second light-emitting element (LE1, LE2) are added to form a light beam.

Abstract: A method for producing an optoelectronic semiconductor chip based on a nitride semiconductor system is specified. The method comprises the steps of: forming a semiconductor section with at least one p-doped region; and forming a covering layer disposed downstream of the semiconductor section in a growth direction of the semiconductor chip, said covering layer having at least one n-doped semiconductor layer. An activation step suitable for electrically activating the p-doped region is effected before or during the formation of the covering layer. An optoelectronic semiconductor chip which can be produced by the method is additionally specified.

Abstract: A radiation-emitting semiconductor component has an improved radiation efficiency. The semiconductor component has a multilayer structure with an active layer for generating radiation within the multilayer structure and also a window having a first and a second main surface. The multi-layer structure adjoins the first main surface of the window. At least one recess, such as a trench or a pit, is formed in the window from the second main surface for the purpose of increasing the radiation efficiency. The recess preferably has a trapezoidal cross section tapering toward the first main surface and can be produced for example by sawing into the window.

Abstract: A method for producing an optoelectronic component comprising the steps of providing a semiconductor layer sequence having at least one active region, wherein the active region is suitable for emitting electromagnetic radiation during operation, and applying at least one layer on a first surface of the semiconductor layer sequence by means of an ion assisted application method.

Abstract: A light-emitting diode chip (1), in which over a substrate (2), a series of epitaxial layers (3) with a radiation-emitting active structure (4) based on InGaN is disposed. Between the substrate (2) and the active structure (4), a buffer layer (20) is provided. The material or materials of the buffer layer (20) are selected such that their epitaxial surface (6) for the epitaxy of the active structure (4) is unstressed or slightly stressed at their epitaxial temperature. The active structure (4) has In-rich zones (5), disposed laterally side by side relative to the epitaxial plane, in which zones the In content is higher than in other regions of the active structure (4). A preferred method for producing the chip is disclosed.

Abstract: A nitride-based semiconductor component having a semiconductor body (1) with a contact metalization (4) applied thereon. The semiconductor body (1) is provided with a protective layer which, if appropriate, also covers partial regions of the contact metalization (4) and which has a plurality of recesses (5) arranged near to one another.

Abstract: What is specified is an edge emitting semiconductor laser chip comprising a carrier substrate (1), an interlayer (2) promoting adhesion between the carrier substrate (1) and a component structure (50) of the edge emitting semiconductor laser chip, and the component structure (50) comprising an active zone (5) provided for generating radiation.

Abstract: A method for producing an optoelectronic component is disclosed. The method includes the steps of providing a substrate, applying a semiconductor layer sequence to the substrate, applying at least two current expansion layers to the semiconductor layer sequence, applying and patterning a mask layer, patterning the second current expansion layer by means of an etching process during which sidewalls of the mask layer are undercut, patterning the first current expansion layer by means of an etching process during which the sidewalls of the mask layer are undercut at least to a lesser extent than during the patterning of the second current expansion layer, and removing the mask layer.

Abstract: Disclosed are a method of fabricating a quasi-substrate wafer (17) with a subcarrier wafer (4) and a growth layer (120), and a semiconductor body fabricated using such a quasi-substrate wafer (17). In the method of fabricating a quasi-substrate wafer (17), a growth substrate wafer (1) is fabricated that is provided with a separation zone (2) and comprises the desired material of the growth layer (120). The growth substrate wafer (1) is provided with a stress that counteracts a stress generated by the formation of the separation zone, and/or the stress generated by the formation of the separation zone is distributed, by structuring a first main face (101) of the growth substrate wafer (1) and/or the separation zone (2), to a plurality of subregions along the first main face (101). The growth substrate wafer (1) with separation zone (2) exhibits no or only slight bowing.

Abstract: This invention describes a radiation-emitting semiconductor component with the a multilayered structure that contains a radiation-emitting active layer, and a window transparent to radiation that has a first principal face and a second principal face opposite the first principal face, and whose first principal face adjoins the multilayered structure. At least one recess is made in the window, which preferably has the form of an indentation of the second principal face or as an edge excavation. At least one lateral surface of the window or of the recess is provided at least partially with a contact surface. Alternatively or cumulatively, at least one contact surface of the component has a plurality of openings.

Abstract: An optoelectronic component having a semiconductor chip containing a semiconductor layer sequence (6) with a radiation-emitting active zone (4), the semiconductor layer sequence (6) having sidewalls (10). A connection contact (9) is provided for impressing current into the active zone. A first current expansion layer (7) adjoins a semiconductor layer (5) of the semiconductor layer sequence (6) and a second current expansion layer (8) is provided between the semiconductor layer sequence (6) and the connection contact (9). The first current expansion layer (7) has a larger sheet resistance than the second current expansion layer (8) and forms an ohmic contact with the adjoining semiconductor layer (5). The second current expansion layer (8) is applied to a partial region of the first current expansion layer (7) which is at a distance from the sidewalls (10).

Abstract: This invention describes a radiation-emitting semiconductor component with the a multilayered structure (4) that contains a radiation-emitting active layer (5), and a window (1) transparent to radiation that has a first principal face (2) and a second principal face (3) opposite the first principal face (2), and whose first principal face (2) adjoins the multilayered structure (4). At least one recess (8) is made in the window (1), which preferably has the form of an indentation of the second principal face or as an edge excavation. At least one lateral surface of the window (1) or of the recess (8) is provided at least partially with a contact surface (11). Alternatively or cumulatively, at least one contact surface of the component has a plurality of openings (14).

Abstract: Radiation-emitting semiconductor device, method for fabricating same and radiation-emitting optical device. A radiation-emitting semiconductor device with a multilayer structure (100) comprising a radiation-emitting active layer (10), with electrical contacts (30, 40) for impressing a current in the multilayer structure (100) and with a radiotransparent window layer (20). The window layer is arranged exclusively on the side of the multilayer structure (100) facing away from a main direction of radiation of the semiconductor device and has at least one side wall that includes a first side wall portion (20a) which extends obliquely, concavely or in a stepwise manner toward a central axis of the semiconductor device lying perpendicular to the multilayer sequence.

Abstract: A radiation-emitting semiconductor component has an improved radiation efficiency. The semiconductor component has a multilayer structure with an active layer for generating radiation within the multilayer structure and also a window having a first and a second main surface. The multi-layer structure adjoins the first main surface of the window. At least one recess, such as a trench or a pit, is formed in the window from the second main surface for the purpose of increasing the radiation efficiency. The recess preferably has a trapezoidal cross section tapering toward the first main surface and can be produced for example by sawing into the window.

Abstract: An optical semiconductor device with a multiple quantum well structure, in which well layers and barrier layers comprising various types of semiconductor layers are alternately layered, in which device well layers (6a) of a first composition based on a nitride semiconductor material with a first electron energy and barrier layers (6b) of a second composition of a nitride semiconductor material with electron energy which is higher in comparison with the first electron energy are provided, followed, seen in the direction of growth, by a radiation-active quantum well layer (6c), for which the essentially non-radiating well layers (6a) and the barrier layers (6b) arranged in front form a superlattice.

Abstract: An optical semiconductor device with a multiple quantum well structure, in which well layers and barrier layers comprising various types of semiconductor layers are alternately layered, in which device well layers (6a) of a first composition based on a nitride semiconductor material with a first electron energy and barrier layers (6b) of a second composition of a nitride semiconductor material with electron energy which is higher in comparison with the first electron energy are provided, followed, seen in the direction of growth, by a radiation-active quantum well layer (6c), for which the essentially non-radiating well layers (6a) and the barrier layers (6b) arranged in front form a superlattice.