DocumentCode
1537120
Title
How to launch 1 W into single-mode fiber from a single 1.48-μm flared resonator
Author
Delépine, Sylvie ; Gérard, Franck ; Pinquier, A. ; Fillion, T. ; Pasquier, J. ; Locatelli, D. ; Chardon, J.-P. ; Bissessur, Hans K. ; Bouché, N. ; Boubal, Francois R. ; Salet, Paul
Author_Institution
OPTO+, Alcatel Corp. Res. Centre, Marcoussis, France
Volume
7
Issue
2
fYear
2001
Firstpage
111
Lastpage
123
Abstract
The operation of 1.48-μm flared resonators is thoroughly studied, both experimentally and theoretically: the accurate determination of threshold condition as a function of geometrical and material parameters, the study of emission spectra and astigmatism variations as a function of optical power level allow us to better understand the may these devices operate. The origin of modal distortion is then analyzed, and an original solution is proposed to increase the single-transverse-mode power at high injection level: it is shown that implanting the multiple-quantum-well active layer with protons efficiently enhances the filtering capability of the overall structure, and particularly that of the ridge waveguide, by bringing additional lateral absorption losses. The explanation of the filtering mechanism is successfully confirmed by simulations using the beam-propagation method. This technique finally allowed more than 1.3 W of continuous wave (CW) diffraction-limited power at 6 A. Low-modal-gain structures were then realized to reduce modal optical absorption in the implanted structures with a view to maintaining a high external efficiency and a reduced vertical divergence. Finally, a three-lens coupling system was designed and the effects of optical feedback minimized so as to obtain a very high coupling efficiency: with an improved laser design, 1.12 W of CW power were then coupled into single-mode fiber at 6.6 A, which represents 65% of the power emitted by the laser chip
Keywords
aberrations; ion implantation; laser cavity resonators; laser feedback; laser modes; microlenses; optical fibre couplers; quantum well lasers; waveguide lasers; 1.12 W; 1.3 W; 1.48 mum; 1.48-μm flared resonators; CW diffraction-limited power; CW power coupling; astigmatism variations; beam-propagation method; emission spectra; external efficiency; filtering capability; high coupling efficiency; high injection level; laser design; lateral absorption losses; modal distortion; modal optical absorption; multiple-quantum-well active layer; optical feedback minimization; optical power level; proton implantation; ridge waveguide; single-mode fiber; single-transverse-mode power; three-lens coupling system; threshold condition; vertical divergence; Absorption; Fiber lasers; Filtering; Laser feedback; Optical coupling; Optical design; Optical distortion; Optical feedback; Optical filters; Optical resonators;
fLanguage
English
Journal_Title
Selected Topics in Quantum Electronics, IEEE Journal of
Publisher
ieee
ISSN
1077-260X
Type
jour
DOI
10.1109/2944.954119
Filename
954119
Link To Document