Title :
1.3-μm polarization-insensitive optical amplifier structure based on coupled quantum wells
Author :
Zhang, Yumin ; Ruden, P.Paul
Author_Institution :
Dept. of Electr. & Comput. Eng., Minnesota Univ., Minneapolis, MN, USA
fDate :
10/1/1999 12:00:00 AM
Abstract :
We show that polarization-insensitive optical gain over a wide bandwidth can be realized in a coupled pseudomorphic multiple-quantum-well structure. The barrier width is chosen such that heavy-hole subbands are grouped tightly and light-hole subbands are widely separated in energy. For specific strain conditions, the uppermost valence subbands, which have large occupation probability and strongly contribute to the gain, consist of a single light-hole subband and a group of coupled heavy-hole subbands. This arrangement gives rise to balanced gains for the TE and TM polarizations. We present calculated results for 1.3-μm semiconductor optical amplifier structures based on bands calculated in the framework of an eight-band k·p model. Two different material systems are examined, InAlGaAs and GaInAsP, on InP substrates
Keywords :
III-V semiconductors; aluminium compounds; gallium arsenide; gallium compounds; indium compounds; k.p calculations; laser beams; light polarisation; quantum well lasers; semiconductor optical amplifiers; valence bands; 1.3 mum; GaInAsP; GaInAsP-InP; InAlGaAs; InAlGaAs-InP; InP; TE polarizations; TM polarizations; balanced gains; barrier width; coupled heavy-hole subbands; coupled pseudomorphic multiple-quantum-well structure; coupled quantum wells; eight-band k·p model; gain; heavy-hole subbands; light-hole subbands; occupation probability; polarization-insensitive optical amplifier structure; polarization-insensitive optical gain; semiconductor optical amplifier structures; single light-hole subband; strain conditions; valence subbands; wide bandwidth; Bandwidth; Capacitive sensors; Optical amplifiers; Optical coupling; Optical materials; Optical polarization; Quantum well devices; Semiconductor optical amplifiers; Stimulated emission; Tellurium;
Journal_Title :
Quantum Electronics, IEEE Journal of
