Title :
Enhancement of optical bandwidth using high barrier multiquantum well structures
Author :
Xu, M.G. ; Fisher, T.A. ; Dell, J.M.
Author_Institution :
Dept. of Electr. & Electron. Eng., Western Australia Univ., Nedlands, WA, Australia
Abstract :
We demonstrate the enhancement of optical bandwidth for modulators based on the quantum confined Stark effect using high barrier multiquantum well structures. This is achieved by carefully placing the Fabry-Perot mode in the wavelength region where the absorbing layer exhibits anomalous refractive index dispersion in the vicinity of the exciton peaks. The enhancement in both the exciton oscillator strength and the separation between the heavy hole and light hole in high barrier multiquantum well structures ultimately results in the enhancement of optical bandwidth. A simulation example shows an increase of 2.5 nm in optical bandwidth at the cost of a factor of three increase in electric field to obtain the same contrast ratio characteristics as a modulator fabricated with low barrier material
Keywords :
electro-optical modulation; excitons; interface states; oscillator strengths; quantum confined Stark effect; refractive index; semiconductor quantum wells; Fabry-Perot mode; absorbing layer; anomalous refractive index dispersion; contrast ratio characteristics; exciton oscillator strength; exciton peaks; high barrier multiquantum well structures; low barrier material; modulator; optical bandwidth; optical bandwidth enhancement; quantum confined Stark effect; wavelength region; Bandwidth; Excitons; Fabry-Perot; Optical modulation; Optical refraction; Optical variables control; Oscillators; Potential well; Refractive index; Stark effect;
Conference_Titel :
Optoelectronic and Microelectronic Materials Devices, 1998. Proceedings. 1998 Conference on
Conference_Location :
Perth, WA
Print_ISBN :
0-7803-4513-4
DOI :
10.1109/COMMAD.1998.791699
