J. Decker¹, P. Crump¹, J. Fricke¹, A. Maaßdorf¹, M. Traub², U. Witte², T. Brand³, A. Unger³, G. Erbert¹, and G. Tränkle¹

Published in:

IEEE Photonics Technol. Lett., vol. 27, no. 15, pp. 1675-1678 (2015).

Abstract:

Low-fill-factor laser bars composed of five narrow-stripe broad-area lasers (30 µm × 6000 µm) with monolithic spectral stabilization are presented. Each laser on the bar emits at a unique wavelength from 970 to 980 nm with a channel spacing of 2.5 nm. Narrow spectral line width <1 nm per emitter is obtained by implementing 40th Bragg order distributed feedback surface gratings with varied grating periods. The design and fabrication of these laser bars is reviewed, with optimal grating etch depth determined using simulations that combine 2D-simulation of the reflectivity and optical losses of a 40th-order surface grating with coupled mode theory. The selected etch depth delivers a grating coupling coefficient of κL ∼ 0.2, which is shown to be sufficient to suppress lasing in Fabry-Perot modes for narrow line operation across all wavelength channels. However, additional optical scattering losses of the gratings are found to limit output power and efficiency. The final realized minibars deliver 25-W continuous wave output power with a conversion efficiency >40% and operate with a beam parameter product of ∼1.6 mm mrad per single emitter, twofold improved in comparison with typical 90-µm wide broad area laser. Such laser minibars are an attractive source for brilliant dense spectral beam combining.

Index Terms:

High power, narrow stripe, broad area lasers, high brightness, semiconductor laser arrays, distributed feedback lasers, surface gratings, dense spectral beam combining.

© Copyright 2015 IEEE - All Rights Reserved. Personal use of this material is permitted. However, permission to reprint/republish this material for advertising or promotional purposes or for creating new collective works for resale or redistribution to servers or lists, or to reuse any copyrighted component of this work in other works must be obtained from the IEEE.

Full version in pdf-format.