DocumentCode
1116022
Title
Lateral analysis of quasi-index-guided injection lasers: Transition from gain to index guiding
Author
Agrawal, Govind P.
Author_Institution
AT&T Bell Laboratories, Murray Hill, NJ, USA
Volume
2
Issue
4
fYear
1984
fDate
8/1/1984 12:00:00 AM
Firstpage
537
Lastpage
543
Abstract
In double-heterostructure stripe-geometry semiconductor lasers an effective lateral index step
over the stripe region can be induced through evanescent-field coupling. Such a quasi-index-guided device exhibits a transition from the gain-guided to the index-guided regime when
is progressively increased. Using parameters appropriate to a 1.3-μm InGaAsP laser, the transition is shown to occur around
. The exact value of
depends on the extent of carrier-induced antiguiding. In the transition region the threshold current decreases rapidly, the lateral mode contracts, and the far field changes from a twin-lobe to a single-lobe pattern. Our analysis suggests that a quasi-index-guided device operates most efficiently for values of
at which the index-guided regime is just approached. With a further increase of
, the mismatch between the gain and mode profiles leads to lower differential quantum efficiencies. Among other structures, the analysis is applicable to a ridge waveguide laser. For a 1.3-μm laser the optimum
can be obtained using 0.2-μm-thick cladding layers for a 0.2-μm thick active layer.
over the stripe region can be induced through evanescent-field coupling. Such a quasi-index-guided device exhibits a transition from the gain-guided to the index-guided regime when
is progressively increased. Using parameters appropriate to a 1.3-μm InGaAsP laser, the transition is shown to occur around
. The exact value of
depends on the extent of carrier-induced antiguiding. In the transition region the threshold current decreases rapidly, the lateral mode contracts, and the far field changes from a twin-lobe to a single-lobe pattern. Our analysis suggests that a quasi-index-guided device operates most efficiently for values of
at which the index-guided regime is just approached. With a further increase of
, the mismatch between the gain and mode profiles leads to lower differential quantum efficiencies. Among other structures, the analysis is applicable to a ridge waveguide laser. For a 1.3-μm laser the optimum
can be obtained using 0.2-μm-thick cladding layers for a 0.2-μm thick active layer.Keywords
Semiconductor lasers; Contracts; Laser modes; Laser theory; Laser transitions; Optical coupling; Optical refraction; Optical waveguides; Planar waveguides; Semiconductor lasers; Waveguide lasers;
fLanguage
English
Journal_Title
Lightwave Technology, Journal of
Publisher
ieee
ISSN
0733-8724
Type
jour
DOI
10.1109/JLT.1984.1073643
Filename
1073643
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