Abstract: A surface emitting semiconductor body with a vertical emission direction is specified, which is provided for operation with a resonator and comprises a semiconductor layer sequence with an active region, wherein the semiconductor body is embodied in wavelength-stabilizing fashion in such a way that a peak wavelength of the radiation generated in the active region, in a predetermined operating range of the semiconductor body, is stabilized with respect to changes in the output power of the radiation generated in the active region.

Abstract: Disclosed is a semiconductor laser. The semiconductor laser includes a semiconductor chip that includes an active layer and emits radiation in a main radiating direction. The active layer is structured in a direction perpendicular to the main radiating direction to reduce heating of the semiconductor chip by spontaneously emitted radiation, and the active layer has the form of a mesa that comprises side walls that form a resonator in such a way as to reduce the spontaneous emission in the active layer in a direction perpendicular to the main radiating direction.

Abstract: An edge emitting semiconductor laser containing a plurality of monolithically integrated laser diodes (1, 2, 3). Each laser diode (1, 2, 3) contains an active zone (11, 12, 13), with the active zones (11, 12, 13) being in each case arranged between waveguide layers (6), the waveguide layers (6) in each case adjoining a cladding layer (7, 8) at a side remote from the active zone (11, 12, 13). The cladding layers (7, 8) comprise inner cladding layers (7), which are arranged above a bottommost active zone (11) and below a topmost active zone (13), and outer cladding layers (8) which are arranged below the bottommost active zone (11) or above the topmost active zone (13). The inner cladding layers (7) have a smaller thickness than the outer cladding layers (8).

Abstract: A surface emitting semiconductor laser device, having at least one monolithically integrated pump radiation source (20), in which the pump radiation source (20) has at least one edge emitting semiconductor structure (9) that is suitable for emission of electromagnetic radiation whose intensity profile transversely with respect to the emission direction (z) of the semiconductor structure follows a predeterminable curve. Such a surface emitting semiconductor laser device emits electromagnetic radiation having a particularly good beam quality.

Abstract: An optoelectronic semiconductor component has a semiconductor body (1) comprising a surface emitting vertical emitter region (2) comprising a vertical emitter layer (3), at least one pump source (4) provided for optically pumping the vertical emitter layer (3), and a radiation passage area (26) through which electromagnetic radiation (31) generated in the vertical emitter layer leaves the semiconductor body (1), wherein the pump source (4) and the vertical emitter layer (3) are at a distance from one another in a vertical direction.

Abstract: A surface-emitting semiconductor laser component, in particular an electrically pumped semiconductor laser component, featuring emission in a vertical direction. The component is provided for the generation of laser radiation by means of an external optical resonator (4, 5). The component comprises a semiconductor body with a semiconductor layer sequence (2) having a lateral main direction of extension and an active zone (3) provided for generation of radiation. A radiation-transmissive contact layer (6) is arranged within the resonator and is electrically conductively connected to the semiconductor body.

Abstract: Disclosed is a semiconductor laser. The semiconductor laser includes a semiconductor chip that includes an active layer and emits radiation in a main radiating direction. The active layer is structured in a direction perpendicular to the main radiating direction to reduce heating of the semiconductor chip by spontaneously emitted radiation. The active layer includes a region provided for optical pumping by a pump radiation source. The optically pumped region of the active layer is surrounded by a region having, in a direction perpendicular to the main radiating direction, a periodic structure that forms a photonic crystal in which radiation having the emission wavelength is not capable of propagation.

Abstract: A laser arrangement has at least one laser diode apparatus with a side surface which laterally limits the laser diode apparatus. The laser arrangement has a plurality of active regions arranged laterally side by side and configured to generate radiation. The laser diode apparatus is arranged on a mount. The distance between the side surface and an edge which laterally limits the mount on the part of the side surface is shorter than the distance between the side surface and the active region closest to the side surface. Additionally or alternatively, the distance between the side surface and the edge is shorter than one of the distances between two adjacent active regions of the laser diode apparatus.

Abstract: A semiconductor laser device comprising an optically pumped surface-emitting vertical emitter region (2) which has an active radiation-emitting vertical emitter layer (3) and has at least one monolithically integrated pump radiation source (5) for optically pumping the vertical emitter region (2), which has an active radiation-emitting pump layer (6). The pump layer (6) follows the vertical emitter layer (3) in the vertical direction and a conductive layer (13) is provided between the vertical emitter layer (3) and the pump layer (6). Furthermore, a contact (9) is applied on the side of the semiconductor laser device which is closer to the pump layer (6) than to the conductive layer (13). An electrical field can be applied between this contact (9) and the conductive layer (13) for generating pump radiation (7) by charge carrier injection.

Abstract: A method for producing an integrated semiconductor component comprising a first semiconductor layer construction for emitting radiation and a second semiconductor layer construction for receiving radiation, wherein a substrate is first provided and a first semiconductor layer sequence containing a radiation-generating region is deposited epitaxially on the substrate. A second semiconductor layer sequence containing a radiation-absorbing region is subsequently deposited epitaxially on the first semiconductor layer sequence. The second semiconductor layer sequence is then patterned in order to uncover a first location and a second location. A first semiconductor layer construction is electrically insulated from a second semiconductor layer construction. Finally, a first contact layer is applied to a free surface of the substrate and a second contact layer is applied at least to the first and second locations for contact-connection.

Abstract: A vertically emitting semiconductor laser with an external resonator, a semiconductor body (1) in which a quantum well structure (4) is located as active zone that includes quantum wells (6) and barrier layers (5) situated therebetween, and at least one pumping radiation source (9) for irradiating into the active zone at an incidence angle ?p pumping radiation (10) of wavelength ?p. The wavelength ?p and the incidence angle ?p of the pumping radiation are selected in such a way that the absorption of the pumping radiation takes place substantially inside the quantum wells. This avoids the losses during the capture of charge carriers from the barrier layers into the quantum wells that occur in the case of optically pumped semiconductor lasers where the pumping radiation is absorbed in the barrier layers.

Abstract: A semiconductor laser is embodied as a surface emitting thin-film semiconductor laser (2) with a semiconductor body (4). The semiconductor body (4) comprises a first and a second planar surface (12, 14). The semiconductor body (4) comprises between the planar surfaces at least one active layer (10) for generating radiation. The semiconductor body (4) has, for coupling out the radiation from the active layer (10) toward the first planar surface (12), at least one first mirror area (26) inclined with respect to the active layer (10).

Abstract: A laser diode apparatus (2) having a plurality of active regions (4a . . . 4n) which are arranged side by side and are designed for radiation production when the laser diode apparatus is in operation. A lateral dimension (ba . . . bn) of the active regions is varied in the lateral direction, and/or the distance (Da . . . D1) between adjacent active regions is varied in the lateral direction. Furthermore, a laser arrangement (1) is specified, having a laser diode apparatus which is arranged on a mount (6) with the mount being matched to the laser diode apparatus. Furthermore, a laser which is optically pumped by means of the laser diode apparatus or the laser arrangement is specified.

Abstract: Disclosed is a semiconductor laser. The semiconductor laser includes a semiconductor chip that includes an active layer and emits radiation in a main radiating direction. The active layer is structured in a direction perpendicular to the main radiating direction to reduce heating of the semiconductor chip by spontaneously emitted radiation, and the active layer has the form of a mesa that comprises side walls that form a resonator in such a way as to reduce the spontaneous emission in the active layer in a direction perpendicular to the main radiating direction.

Abstract: Disclosed is a semiconductor laser. The semiconductor laser includes a semiconductor chip that includes an active layer and emits radiation in a main radiating direction. The active layer is structured in a direction perpendicular to the main radiating direction to reduce heating of the semiconductor chip by spontaneously emitted radiation. The active layer includes a region provided for optical pumping by a pump radiation source. The optically pumped region of the active layer is surrounded by a region having, in a direction perpendicular to the main radiating direction, a periodic structure that forms a photonic crystal in which radiation having the emission wavelength is not capable of propagation.

Abstract: An optically pumped semiconductor laser device having a surface-emitting vertical emission region (1) and at least one monolithically integrated pump radiation source (2) for optically pumping the vertical emission region (1). The semiconductor laser device is distinguished by the fact that the pump radiation enters the vertical emission region (1) in the form of partial bundles of rays of radiation with different radiation directions so that the pump radiation and the fundamental mode of the vertical emission region (1) have an overlap which is suitable for the excitation of this fundamental mode. This device is based on the fact that the fundamental mode of the vertical emission region (1) is preferably excited when the spatial intensity distribution of the pump radiation matches the profile of the fundamental mode.

Abstract: A surface-emitting semiconductor laser component, in particular an electrically pumped semiconductor laser component, featuring emission in a vertical direction. The component is provided for the generation of laser radiation by means of an external optical resonator (4, 5). The component comprises a semiconductor body with a semiconductor layer sequence (2) having a lateral main direction of extension and an active zone (3) provided for generation of radiation. A radiation-transmissive contact layer (6) is arranged within the resonator and is electrically conductively connected to the semiconductor body.

Abstract: A method for producing an integrated semiconductor component comprising a first semiconductor layer construction for emitting radiation and a second semiconductor layer construction for receiving radiation, wherein a substrate is first provided and a first semiconductor layer sequence containing a radiation-generating region is deposited epitaxially on the substrate. A second semiconductor layer sequence containing a radiation-absorbing region is subsequently deposited epitaxially on the first semiconductor layer sequence. The second semiconductor layer sequence is then patterned in order to uncover a first location and a second location. A first semiconductor layer construction is electrically insulated from a second semiconductor layer construction. Finally, a first contact layer is applied to a free surface of the substrate and a second contact layer is applied at least to the first and second locations for contact-connection.

Abstract: An edge emitting semiconductor laser containing a plurality of monolithically integrated laser diodes (1, 2, 3). Each laser diode (1, 2, 3) contains an active zone (11, 12, 13), with the active zones (11, 12, 13) being in each case arranged between waveguide layers (6), the waveguide layers (6) in each case adjoining a cladding layer (7, 8) at a side remote from the active zone (11, 12, 13). The cladding layers (7, 8) comprise inner cladding layers (7), which are arranged above a bottommost active zone (11) and below a topmost active zone (13), and outer cladding layers (8) which are arranged below the bottommost active zone (11) or above the topmost active zone (13). The inner cladding layers (7) have a smaller thickness than the outer cladding layers (8).

Abstract: A semiconductor laser having a semiconductor chip (1) which contains an active layer (5) and emits radiation in a main radiating direction (6). The active layer (5) is structured in a direction perpendicular to the main radiating direction (6) in order to reduce heating of the semiconductor chip (1) by spontaneously emitted radiation (10).