Abstract: The present invention relates to an arrangement of semiconductor diode lasers stacked on top of one another, which is arranged on a substrate (1). A first diode laser (12) is arranged on the substrate (1), and a second diode laser (13) is arranged on the first diode laser (12). Between the first diode laser (12) and the second diode laser (13) there is a contact layer (6). The contact layer (6) comprises a first conductive layer (18) of a first conduction type and a second conductive layer (20) of a second conduction type and an interlayer (19) which is arranged between the first and second conductive layers (18, 20).

Abstract: According to the invention, a semiconductor component for the emission of electromagnetic radiation, especially light, is made that has the following features: an active layer for producing radiation, a p-type contact that is electrically connected to the active layer, an n-type contact that is electrically connected to the active layer, and a current-confining structure to define a current path, with the current-confining structure being provided between the n-type contact and the active layer.

Abstract: The invention is directed to an optically pumped surface-emitting semiconductor laser device having at least one radiation-generating quantum well structure and at least one pump radiation source for optically pumping the quantum well structure, whereby the pump radiation source comprises an edge-emitting semiconductor structure. The radiation-generating quantum well structure and the edge-emitting semiconductor structure are epitaxially grown on a common substrate. A very efficient and uniform optical pumping of the radiation-generating quantum well structure is advantageously possible with this monolithically produced semiconductor laser device. Methods for manufacturing inventive semiconductor laser devices are also specified.

Abstract: A device for emission of laser radiation includes at least one semiconductor laser having a resonator and a pumped active zone disposed within the resonator. The zone is subdivided into at least two spatially separated active zones by free-radiation regions without lateral wave guidance. Preferably, the laser is at least two semiconductor lasers disposed in series, a row, or a line, each having an antireflection coating on at least one side. The lasers have outer mirror elements at an end of the lasers disposed in series and the outer mirror elements form the resonator. A laser configuration includes two opposite semiconductor lasers from which a fundamental mode is in each case imaged into the active zone of the opposite semiconductor laser. The laser configuration has an emerging laser beam with little divergence.

Abstract: A semiconductor laser has a semiconductor body with first and second main areas, preferably each provided with a contact area, and also first and second mirror areas. An active layer and a current-carrying layer are formed between the main areas. The current-carrying layer has at least one strip-type resistance region, which runs transversely with respect to the resonator axis and whose sheet resistivity is increased at least in partial regions compared with the regions of the current-carrying layer that adjoin the resistance region.

Abstract: In an optically pumpable surface-emitting semiconductor laser device with a vertical emitter with a radiation-generating active layer, at least one modulation radiation source for modulating the output power of the surface-emitting semiconductor device is provided. The modulation radiation source is formed by an edge-emitting semiconductor structure with an active layer, and which is disposed such that during operation it radiates into the radiation-generating active layer of the vertical emitter. This produces an easily modulatable surface-emitting laser source of high power and high beam quality. A pumping radiation source for optically pumping the active layer of the vertical emitter is preferably provided in the semiconductor laser device.

Abstract: According to the invention, a semiconductor component for the emission of electromagnetic radiation, especially light, is made that has the following features: an active layer for producing radiation, a p-type contact that is electrically connected to the active layer, an n-type contact that is electrically connected to the active layer, and a current-confining structure to define a current path, with the current-confining structure being provided between the n-type contact and the active layer.

Abstract: The invention is directed to an optically pumped surface-emitting semiconductor laser device having at least one radiation-generating quantum well structure and at least one pump radiation source for optically pumping the quantum well structure, whereby the pump radiation source comprises an edge-emitting semiconductor structure. The radiation-generating quantum well structure and the edge-emitting semiconductor structure are epitaxially grown on a common substrate. A very efficient and uniform optical pumping of the radiation-generating quantum well structure is advantageously possible with this monolithically produced semiconductor laser device. Methods for manufacturing inventive semiconductor laser devices are also specified.

Abstract: A semiconductor laser device having a multiplicity of individual lasers disposed in a laser-active region within outer boundary surfaces having front and rear boundary surfaces extending crosswise to an exit direction of the laser light, and lateral, bottom and top boundary surfaces extending parallel to the exit direction of the laser light, includes an absorption layer for decoupling photons interfering with desired laser operation, the absorption layer being applied full-surface to all of the outer boundary surfaces of the laser device, except for the laser-active region for at least one of the front and the rear boundary surfaces, respectively, extending crosswise to the exit direction of the laser light, and except for a relatively few locations remaining free for disposing terminal electrodes thereon or for introducing pump light thereat.

Abstract: A radiation emitter component, in particular an infrared emitter component with a conventional light-emitting diode housing, includes two electrode connections, one of which has a well-shaped reflector. The housing has an optically transparent, electrically non-conducting encapsulation material. A semiconductor laser chip is fastened in a well-shaped reflector of the light-emitting diode housing. The semiconductor laser chip has a quantum well structure, in particular with a strained layer structure, for example MOVPE epitaxial layers with a layer sequence GaAlAs-InGaAs-GaAlAs. A diffusor material can be inserted into the optically transparent, electrically non-conducting material of the light-emitting diode housing.

Abstract: In a multiple laser arrangement (1) with a plurality of phase-coupled laser diodes with lateral extremities (2, 3) of the multiple laser arrangement (1) including decoupling means for improving the output radiation of the laser arrangement. An absorbent material (4) or a synthetic material is provided at the lateral extremities (2, 3) for the purpose of reducing undesired transverse modes or ring modes.