The present disclosure relates to a laser diode system. The system may have at least one laser diode emitter having a substrate, at least one laser diode supported on the substrate, and a facet which a laser beam generated by the laser diode is emitted. A cooling subsystem is included which is disposed in contact with the substrate of the laser diode emitter. The cooling subsystem includes a plurality of cooling fins forming a plurality of elongated channels for circulating a cooling fluid therethrough to cool the laser diode emitter. The cooling fluid also flows over the facet of the laser diode emitter.

In various embodiments, the beam parameter product and/or numerical aperture of a laser beam is adjusted utilizing a step-clad optical fiber having a central core, a first cladding, an annular core, and a second cladding.

A light-emitting device includes: a substrate comprising a base; a semiconductor laser element disposed on an upper surface of the base; a sealing member located above the base and fixed to the substrate, wherein the sealing member and the substrate define a sealed space in which the semiconductor laser element is located; and a lens member fixed to the sealing member by adhesive, the lens member comprising a lens section through which light emitted from the semiconductor laser element passes. A space between the sealing member and the lens member is open to an area outside the light-emitting device.

An ultra-compact, high power, fiber pump module apparatus has a heatsink with a stepped outer shape. The heatsink has at least one interior cooling channel. A plurality of single emitter diodes is positioned on one step of the stepped outer shape of the heatsink, respectively. At least two beam-shifting structures are positioned in a beam path of each of the plurality of single emitter diodes. The at least two beam-shifting structures fold each beam emitted from the plurality of single emitter diodes in at least three dimensions. At least one beam combining structure is positioned in the beam path, wherein the at least one beam combining structure combines the beams from each of the plurality of single emitter diodes into a single, combined beam. The single, combined beam is output from the ultra-compact, high power, fiber pump module apparatus.

A laser connection module including: multiple superposed electrodes connected in alternating order with opposite electricity supply poles; at least one laser diode mounted between the opposite surfaces of consecutive electrodes, making contact with them; an external structure delimiting an open space located along a light-emitting area of the laser diodes and suitable for containing the set of superposed electrodes and laser diodes; at least one tightener mounted on a first end of the external structure and which presses the set of electrodes and laser diodes against a second opposite end of the structure, establishing the fixation and mutual contact thereof; and an intermediate protective plate disposed between the at least one tightener and the end electrode closest to the at least one tightener.

An optical fiber support structure includes: a first portion configured to support an optical fiber including a core wire and a covering surrounding the core wire, the core wire including a core and a cladding; a second portion attached to the first portion; and a relaxing portion that is connected to an end portion of the core wire and that is positioned between the first portion and the second portion, the relaxing portion having a light receiving surface configured to receive light input from a space, an area of the light receiving surface being larger than an area of the end portion of the core wire.

A semiconductor laser module comprises a tapered laser diode and/or a tapered amplifier diode equipped with beam shaping optics. The tapered laser diode and/or the tapered amplifier diode includes an emission facet for emitting a laser beam along a beam axis. The beam-shaping optics comprise a plano-convex cylindrical lens oriented so as to change divergence of the beam in the fast axis direction, the plano-convex spherical cylindrical lens having a planar surface arranged facing the facet and a circular cylindrical surface facing away from the facet. The refractive index of lens may be uniform throughout the entire lens. Alternatively, the lens may have a refractive index varying in the direction of the slow axis and/or in the direction of the fast axis.

In various embodiments, pointing errors in a non-wavelength-beam-combining dimension of a laser system are at least partially alleviated via staircased collimation lenses.

An apparatus for stacking and coating of very short cavity laser diode arrays. The apparatus includes an array holder fixture to securely hold the very short cavity laser diode arrays and spacer arrays, and a stacking plate. The array holder fixture including a top-side presser to secure a stack of very short cavity laser arrays and spacer arrays from a first end of the stack, a bottom-side presser to secure the stack of very short cavity laser arrays and spacer arrays from a second end of the stack, and a pair of side clamps. The array holder fixture is operatively coupled to the stacking plate during the stacking of the very short cavity laser diode arrays and spacer arrays.

A system and method for providing laser diodes with broad spectrum is described. GaN-based laser diodes with broad or multi-peaked spectral output operating are obtained in various configurations by having a single laser diode device generating multiple-peak spectral outputs, operate in superluminescene mode, or by use of an RF source and/or a feedback signal. In some other embodiments, multi-peak outputs are achieved by having multiple laser devices output different lasers at different wavelengths.