Abstract: A semiconductor chip has a substrate that is in the form of a parallelepiped whose side surfaces are shaped as tilted parallelograms. Such a semiconductor chip has a high output efficiency and a homogeneous thermal load due to having at least two side surfaces that are provided with an acute angle and are in the form of parallelograms.

Abstract: A semiconductor chip has a substrate that is in the form of a parallelepiped whose side surfaces are shaped as tilted parallelograms. Such a semiconductor chip has a high output efficiency and a homogeneous thermal load due to having at least two side surfaces that are provided with an acute angle and are in the form of parallelograms.

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

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 chip (2) with a radiation-transmissive window (5), which has a refractive index nF and has a main area (19), with a multilayer structure (9), which contains a radiation-active layer (10) and adjoins the main area (19) of the window (5), and with a radiation-transmissive medium surrounding the window (5) and having the refractive index n0, the window (5) having at least two boundary areas (6, 7), which form an angle &bgr;, for which the relationship

Abstract: A method is provided for fabricating a useful layer containing at least one semiconductor layer, in which the useful layer is separated from a carrier. In this case, the useful layer is applied to the carrier and an auxiliary carrier is applied to that side of the useful layer that is remote from the carrier by a connecting layer at a joining temperature. Afterward, the carrier is stripped away at a temperature that is greater than or equal to the joining temperature and is less than the melting point of the connecting layer. At least a part of the useful layer together with the auxiliary carrier is removed from the carrier.

Abstract: A radiation-emitting structural element with a multi-layer structure, which includes an active layer with at least one radiation-generating surface, and a radiation-permeable window with a main surface, on which the multi-layer structure is placed.

Abstract: Semiconductor chip which emits electromagnetic radiation, and method for fabricating it. To improve the light yield of semiconductor chips which emit electromagnetic radiation, a textured reflection surface (131) is integrated on the p-side of a semiconductor chip. The semiconductor chip has an epitaxially produced semiconductor layer stack (1) based on GaN, which comprises an n-conducting semiconductor layer (11), a p-conducting semiconductor layer (13) and an electromagnetic radiation generating region (12) which is arranged between these two semiconductor layers (11, 13). The surface of the p-conducting semiconductor layer (13) which faces away from the radiation-generating region (12) is provided with three-dimensional pyramid-like structures (15). A mirror layer (40) is arranged over the whole of this textured surface. A textured reflection surface (131) is formed between the mirror layer (40) and the p-conducting semiconductor layer (13).

Abstract: A radiation-emitting semiconductor device with a multilayer structure comprising a radiation-emitting active layer, with electrical contacts for impressing a current in the multilayer structure and with a radiotransparent window layer. The window layer is arranged exclusively on the side of the multilayer structure 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 which extends obliquely, concavely or in a stepwise manner toward a central axis of the semiconductor device lying perpendicular to the multilayer sequence. In its subsequent extension toward the back side, viewed from the multilayer structure, the side wall changes over into a second side wall portion that extends perpendicularly to the multilayer structure, that is, parallel to the central axis, and the portion of the window layer encompassing the second side wall portion forms a mounting pedestal for the semiconductor device.

Abstract: This invention describes a radiation-emitting semiconductor component based on GaN, whose semiconductor body is made up of a stack of different GaN semiconductor layers (1). The semiconductor body has a first principal surface (3) and a second principal surface (4), with the radiation produced being emitted through the first principal surface (3) and with a reflector (6) being produced on the second principal surface (4).

Abstract: A light-emitting diode (1) has a lens body (3) that is fabricated from an inorganic solid. Fastened on the lens body (3) are semiconductor chips (2) that emit light beams (18). Furthermore, the light-emitting diode (1) is provided with a housing (20) that can be screwed into a conventional lamp holder via a thread (21).

Abstract: A light-emitting chip (3) has a lens-type coupling-out window (4), whose base area (5) is provided with a mirror area (6). Arranged on a coupling-out area (7) of the coupling-out window (4) is a layer sequence (9), with a photon-emitting pn junction (10). The photons emitted by the pn junction are reflected at the mirror area (6) and can leave the coupling-out window (4) through the coupling-out area (7).

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 semiconductor component has a plurality of GaN-based layers, which are preferably used to generate radiation, produced in a fabrication process. In the process, the plurality of GaN-based layers are applied to a composite substrate that includes a substrate body and an interlayer. A coefficient of thermal expansion of the substrate body is similar to or preferably greater than the coefficient of thermal expansion of the GaN-based layers, and the GaN-based layers are deposited on the interlayer. The interlayer and the substrate body are preferably joined by a wafer bonding process.

Abstract: Recesses interrupt an active layer on a semiconductor chip to improve the coupling out of light. As a result, side faces of the active layer appear, as seen from a light-generating point, at a large solid angle and the paths of light in the active layer are shortened.

Abstract: A luminescent diode chip for flip-chip mounting on a carrier, having a conductive substrate (12), a semiconductor body (14) that contains a photon-emitting active zone and that is joined by an underside to the substrate (12), and a contact (18), disposed on a top side of the semiconductor body (14), for making an electrically conductive connection with the carrier (30) upon the flip-chip mounting of the chip, whereby either the carrier is solder covered or a layer of solder is applied to the contact. An insulating means (40, 42, 44, 46, 48) is provided on the chip, for electrically insulating free faces of the semiconductor body (14) and free surfaces of the substrate (12) from the solder.

Abstract: Radiation-emitting semiconductor device, method for fabricating same and radiation-emitting optical device

Abstract: A radiation-emitting structural element with a multi-layer structure, which includes an active layer with at least one radiation-generating surface, and a radiation-permeable window with a main surface, on which the multi-layer structure is placed.

Abstract: A radiation-emitting semiconductor component has a semiconductor body containing a nitride compound semiconductor, and a contact metallization layer disposed on a surface of the semiconductor body. In this case, the contact metallization layer is covered with a radiation-transmissive, electrically conductive contact layer. The radiation generated is coupled out through the contact metallization layer or through openings in the contact metallization layer.

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).