Title :
High-power and high-speed performance of 1.3-μm strained MQW gain-coupled DFB lasers
Author :
Lu, Hanh ; Blaauw, Case ; Benyon, Bill ; Ping Li, Guo ; Makino, Toshihiko
Author_Institution :
Bell-Northern Res., Ottawa, Ont., Canada
fDate :
6/1/1995 12:00:00 AM
Abstract :
In-phase gain-coupled distributed feedback (DFB) lasers with etched quantum-well active-layers emitting at 1.3-μm wavelength have been fabricated for the first time. High optical output power up to 50 mW was achieved while single-mode operation was maintained at the longer wavelength side of the Bragg stop band because the in-phase gain coupling effect favors this wavelength. With the optimization of the strained-layer multi-quantum wells (MQW) in the active region, a large effective differential gain of 7.5-19×10-16 cm2 , a high modulation bandwidth of 18 GHz, and high temperature operation up to 100°C were obtained when the DFB wavelength was not detuned from the material gain peak
Keywords :
distributed feedback lasers; etching; laser modes; laser theory; optical couplers; optical modulation; quantum well lasers; 1.3 mum; 1.3-μm strained MQW gain-coupled DFB lasers; 100 C; 18 GHz; 50 mW; Bragg stop band; DFB wavelength; etched; high modulation bandwidth; high optical output power; high temperature operation; high-power performance; high-speed performance; in-phase gain coupling effect; in-phase gain-coupled distributed feedback lasers; large effective differential gain; longer wavelength side; material gain peak; optimization; quantum-well active-layers; single-mode operation; strained-layer multi-quantum wells; Distributed feedback devices; Etching; High speed optical techniques; Laser feedback; Optical coupling; Optical feedback; Power generation; Quantum well devices; Quantum well lasers; Stimulated emission;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/2944.401218
