A disclosed semiconductor laser module includes a semiconductor laser device; a waveguide optical function device that has an incidence end on which laser light emitted from the semiconductor laser device is incident and that guides the incident light; and a protrusion that is provided on an extension line of a light path of the laser light emitted from the semiconductor laser device, the extension line extending beyond the incidence end.

The semiconductor laser element includes: a substrate; a first semiconductor layer disposed above a main surface of the substrate; an active layer that is disposed above the first semiconductor layer and generates light; and a second semiconductor layer) disposed above the active layer. In a top view of a front-side end portion of the semiconductor laser element from which the light is emitted, an end surface of the second semiconductor layer includes an inclined portion with respect to an end surface of the first semiconductor layer.

A QCL may include a substrate, an emitting facet, and semiconductor layers adjacent the substrate and defining an active region. The active region may have a longitudinal axis canted at an oblique angle to the emitting facet of the substrate. The QCL may include an optical grating being adjacent the active region and configured to emit one of a CW laser output or a pulsed laser output through the emitting facet of substrate.

A semiconductor laser is provided that includes a semiconductor layer sequence and electrical contact surfaces. The semiconductor layer sequence includes a waveguide with an active zone. Furthermore, the semiconductor layer sequence includes a first and a second cladding layer, between which the waveguide is located. At least one oblique facet is formed on the semiconductor layer sequence, which has an angle of 45° to a resonator axis with a tolerance of at most 10°. This facet forms a reflection surface towards the first cladding layer for laser radiation generated during operation. A maximum thickness of the first cladding layer is between 0.5 M/n and 10 M/n at least in a radiation passage region, wherein n is the average refractive index of the first cladding layer and M is the vacuum wavelength of maximum intensity of the laser radiation.

An optoelectronic semiconductor laser component may include at least two laser units. The semiconductor laser component may have an output coupling surface configured to generate electromagnetic radiation in the semiconductor laser component. Each laser unit may include a laser resonator having a resonator axis, an output coupling mirror and a first and a second resonator mirror with a primary section of the resonator axis running laterally therebetween. The output coupling mirror may be formed by a partial region of the output coupling surface. Along the primary section of the resonator axis at least one contact strip is arranged on the output coupling surface, and extends to a metallic connection surface. The laser units may be aligned in such a way that the primary sections of the resonator axes run parallel to one another and the output coupling mirrors face one another.

A method for manufacturing an optical device includes providing a carrier waver, provide a first substrate having a first surface region, and forming a first gallium and nitrogen containing epitaxial material overlying the first surface region. The first epitaxial material includes a first release material overlying the first substrate. The method also includes patterning the first epitaxial material to form a plurality of first dice arranged in an array; forming a first interface region overlying the first epitaxial material; bonding the first interface region of at least a fraction of the plurality of first dice to the carrier wafer to form bonded structures; releasing the bonded structures to transfer a first plurality of dice to the carrier wafer, the first plurality of dice transferred to the carrier wafer forming mesa regions on the carrier wafer; and forming an optical waveguide in each of the mesa regions, the optical waveguide configured as a cavity to form a laser diode of the electromagnetic radiation.

An optical semiconductor device includes: a semiconductor substrate including a first main surface and a second main surface; a stacked body that is formed on the first main surface and includes an active layer and a contact layer arranged on a side opposite to the semiconductor substrate with respect to the active layer; a first electrode in contact with the contact layer; and a second electrode formed on the second main surface. The stacked body includes a light transmitting portion formed by not covering at least part of a surface of the contact layer on a side opposite to the semiconductor substrate with the first electrode. The optical semiconductor device is configured such that a waveguide mode is not formed by current application through the first electrode and the second electrode in a state in which the light transmitting portion is not in optical contact with an external member.

A QCL may include a substrate, an emitting facet, and semiconductor layers adjacent the substrate and defining an active region. The active region may have a longitudinal axis canted at an oblique angle to the emitting facet of the substrate. The QCL may include an optical grating being adjacent the active region and configured to emit one of a CW laser output or a pulsed laser output through the emitting facet of substrate.

Techniques for efficient alignment of a semiconductor laser in a Photonic Integrated Circuit (PIC) are disclosed. In some embodiments, a photonic integrated circuit (PIC) may include a semiconductor laser that includes a laser mating surface, and a substrate that includes a substrate mating surface. A shape of the laser mating surface and a shape of the substrate mating surface may be configured to align the semiconductor laser with the substrate in three dimensions.

A radiation-emitting semiconductor chip includes a semiconductor layer sequence having an active layer for generating electromagnetic radiation. The semiconductor chip also includes a reflector at a side surface of the semiconductor layer sequence having a reflector surface facing the semiconductor layer sequence and extending obliquely with respect to the active layer. The semiconductor chip further includes a top surface extending transversely with respect to the reflector surface and having a first emission region. The semiconductor chip additionally includes a further reflector situated opposite the reflector. The semiconductor chip is configured such that electromagnetic radiation generated in the active layer during operation is reflected by the reflector and emerges from the semiconductor chip via the emission region of the top surface. A main emission direction of the emerging electromagnetic radiation together with the active layer form an emergence angle of between 30° and 80° inclusive.