Hg. Treusch et al., High-brightness semiconductor laser sources for materials processing: Stacking, beam shaping, and bars, IEEE S T QU, 6(4), 2000, pp. 601-614
A compact, reliable semiconductor laser source for materials processing, me
dical, and pumping applications is described. This industrial laser source
relies on a combination of technologies that have matured in recent years.
In particular, effective means of stacking and imaging monolithic semicondu
ctor laser arrays (a.k.a., bars), together with advances in the design and
manufacture of the bars, have enabled the production of robust sources at m
arket-competitive costs. Semiconductor lasers are presently the only lasers
known that combine an efficiency of about 50% with compact size and high r
eliability. Currently the maximum demonstrated output power of a 10-mm-wide
semiconductor laser bar exceeds the 260 W level when assembled on an activ
ely cooled heat sink. (The rated power is in the range of 50-100 W.) Power
levels in the kilowatt range can be reached by stacking such devices.
The requirements on the stacking technique and the optic assembly to achiev
e high brightness are discussed. Optics for beam collimation in fast and sl
ow axis are compared. An example for an optical setup to use in materials p
rocessing will be shown. Spot sizes as low as 0.4 mm x 1.2 mm at a numerica
l aperture of 0.3 and output power of 1 kW are demonstrated. This results i
n a power density of more than 200 kW/cm(2). A setup for further increase i
n brightness by wavelength and polarization coupling will be outlined. For
incoherent coupling of multiple beams into a single core optical fiber, a s
ophisticated beam-shaping device is needed to homogenize the beam quality o
f stacked semiconductor lasers.
Applications economics dictate that reliable operation is achievable at num
erous wavelengths (both for wavelength-specific applications and for bright
ness scaling through geometric wavelength multiplexing) and at ever higher
per bar power levels. New material systems and epitaxial structures continu
e to be evaluated in this pursuit. Here we include details of designs and p
erformance for devices operating at 808, 830, and 915 nm. These include cha
racteristics of both single-emitter devices and bars.