DocumentCode
1555134
Title
Improved coupling efficiency of a strained InGaAs-AlGaAs quantum-well laser into a fiber Bragg grating
Author
Temmyo, J. ; Sugo, M. ; Nishiya, T. ; Tamamura, T. ; Bilodeau, F. ; Hill, K.O.
Author_Institution
NTT Opto-Electron. Labs., Kanagawa, Japan
Volume
9
Issue
5
fYear
1997
fDate
5/1/1997 12:00:00 AM
Firstpage
581
Lastpage
583
Abstract
We describe a highly efficient coupling of up to 78% into a single mode fiber (SMF) by utilizing a low-divergence-angle InGaAs-AlGaAs laser and a new high-NA aspheric lens, resulting in the coupled optical output of over 300 mW with a kink-free performance. The kink-free 300 mW of fiber-coupled power is the largest power reported from a diode laser wavelength stabilized using a fiber Bragg grating. A 3% fiber Bragg grating makes the optical output stabilize at a wavelength of 1.016 μm for an optical output power up to 310 mW and without any distinct decrease of the optical output. The coupling tolerance for lateral offsets is improved by utilizing a thermal-diffused expanded-core technique even in the case of using a high-NA coupling aspheric lens. We have also achieved a 300-mW fiber-coupled wavelength-stabilized InGaAs-AlGaAs semiconductor laser butterfly module using a fiber Bragg grating.
Keywords
III-V semiconductors; aluminium compounds; aspherical optics; diffraction gratings; gallium arsenide; indium compounds; laser beams; laser frequency stability; lenses; optical fibre couplers; quantum well lasers; 1.016 mum; 300 to 310 mW; 78 percent; InGaAs-AlGaAs; coupled optical output; coupling efficiency; coupling tolerance; diode laser wavelength; fiber Bragg grating; fiber-coupled power; fiber-coupled wavelength-stabilized InGaAs-AlGaAs semiconductor laser butterfly module; high-NA aspheric lens; highly efficient coupling; kink-free performance; lateral offsets; low-divergence-angle InGaAs-AlGaAs laser; optical output; single mode fiber; strained InGaAs-AlGaAs quantum-well laser; thermal-diffused expanded-core technique; Diode lasers; Fiber lasers; Laser modes; Lenses; Optical coupling; Power generation; Quantum well lasers; Semiconductor lasers; Thermal expansion; Thermal lensing;
fLanguage
English
Journal_Title
Photonics Technology Letters, IEEE
Publisher
ieee
ISSN
1041-1135
Type
jour
DOI
10.1109/68.588123
Filename
588123
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