Laser diodes formed on a common substrate with layers of suitable thickness and refractive indices produce output beams that are coherently coupled. A phase mask can be situated to produce phase differences in one or more of the output beams to produce a common wavefront phase. The phase-corrected beams propagate with reduced angular divergence than conventional lasers that are not coherently coupled, and the coherently coupled laser diodes can provide higher beam brightness, enhanced beam parameter product, and superior power coupled into doped fibers in fiber lasers.

To provide a laser oscillator, in which an LD module is fixed to a cooling plate through insulated fixation that is superior in durability, cost, and workability in an insulated fixation operation. A laser oscillator includes an LD module. The LD module has one or a plurality of LD light source(s), and is placed on a thermally conductive insulating member placed on a cooling plate. The LD module of the laser oscillator is fixed to the cooling plate, via an elastic insulating member fixed to the cooling plate.

The system and method for modifying the output beam parameters of a plurality of laser diode array sources comprises scalable pump sources for use with diode pumped alkali lasers. The present invention optimizes a diode laser pump source by spectrally-narrowing stacks of diode laser array bars using a single external cavity outfitted with a proprietary step-mirror and cylindrical optical elements. The system and method of the present invention multiplies by one-hundred fold the number of stacks that can be narrowed, vastly increasing the attainable power output by utilizing beam-splitters.

A laser apparatus includes a plurality of laser modules each generating a laser line in a working plane. The laser modules are juxtaposed so that the laser lines generated by the modules combine into a single laser line. Each of the laser modules includes at least one laser line generator. The laser line generator includes two linear arrays of strips of laser diodes each emitting a focused laser beam. The two linear arrays are arranged parallel to each other so that the strips are staggered. The two sets of parallel laser beams generated by the two linear arrays of strips, respectively, are merged into a single laser line by a set of mirrors. The linear arrays of strips of laser diodes and the mirrors are arranged so that the two sets of laser beams trace optical paths of the same length before being merged into a single laser line.

A light-emitting device includes: a substrate including a base and a side wall; a plurality of semiconductor laser elements disposed in a row direction and in a column direction on an upper surface of the base; a plurality of pairs of wires that penetrate the side wall in the row direction; and a lens array fixed to the substrate, the lens array comprising a plurality of lens sections disposed in the row direction and in the column direction above the plurality of semiconductor laser elements. Each laser beam that is emitted from the semiconductor laser elements and is incident on a light incident surface of the lens array has a beam shape with a greater width in the column direction than in the row direction.

An adapter element (10) for connecting an electronic component (30) to a heat sink element (20), including an insulation layer (15) extending along a main extension plane (HSE), and at least a first web element (11) and a second web element (12), which are arranged next to each other in a direction parallel to the main extension plane (HSE), forming a free area (13), which, in the assembled state, are arranged between the insulating layer (15) and the electronic component (30) in a direction running perpendicular to the main extension plane (HSE), and on whose front sides (18) facing away from the insulating layer (15) the electronic component (30) is arranged in the assembled state, wherein a distance (A) between the first web element (11) and the second web element (12), measured in a plane parallel to the main extension plane (HSE), is smaller than 350 μm.

An external cavity laser apparatus includes a plurality of laser modules collectively including a plurality of beam emitters that collectively emit a plurality of emitted beams. Each laser module includes a base comprising a plurality of stepped platforms, one of the plurality of beam emitters being secured on each platform of the plurality of stepped platforms, and a plurality of module reflectors, one of the plurality of module reflectors being secured on each of the plurality of stepped platforms to receive radiation from a respective one of the plurality of beam emitters located on a same stepped platform. The external cavity laser apparatus further includes an angular dispersive optic and a polarized beam splitter.

Provided here are: a mounting member having a front surface on which a diffusion bonding layer is formed; an optical semiconductor element provided with a light emitting part therein, and having a rear surface on which a diffusion bonding layer is formed; and an electrode layer formed from the diffusion bonding layer and the diffusion bonding layer by diffusion bonding therebetween; wherein, in the optical semiconductor element, the light emitting part is provided near a side of the optical semiconductor element so as to be displaced toward the mounting member. This configuration not only makes unnecessary the use of a solder, an Ag paste and the like to thereby prevent the light emitting part in the optical semiconductor element from being contaminated by the solder, but also allows the light emitting part to be closer to the mounting member-side to thereby achieve improvement in heat-dissipation capability.

In various embodiments, alignment systems for laser resonators generate near-field and/or far-field images of input beams produced by the laser resonators to enable the alignment of the input beams.

A laser assembly for use with an additive manufacturing system, which includes a base block configured to be moved along a scan direction axis in the additive manufacturing system, a plurality of laser emitters preferably arranged in an array of at least two rows of two or more laser emitters. At least a portion of a heat sink assembly is configured to draw heat away from the base block and/or the laser emitters. The assembly includes a controller assembly a controller assembly configured to control a movement of the base block along the first axis and to independently control at least timing and duration of energy emitted from each laser emitter of the plurality of laser emitters as the base block moves along the first axis.