Title :
Band structure engineering of semiconductor lasers for optical communications
Author :
Yablonovitch, E. ; Kane, E.O.
Author_Institution :
Bell Commun. Res., Red Bank, NJ, USA
fDate :
8/1/1988 12:00:00 AM
Abstract :
Recent advances in epitaxial growth have led to the prospect of artificial modification of the electronic structure or band structure of semiconductor materials. The combination of strain and quantum confinement in the valence band can lead to substantially more favorable energy dispersion relations for laser action than those existing in the natural semiconductor crystal. Numerical results are presented for a series of alloy compositions with a bandgap near the 1.55-μm optimum wavelength for optical communications. The laser threshold current and the intervalence band absorption can be significantly diminished in properly engineered band structures
Keywords :
band structure of crystalline semiconductors and insulators; optical communication; semiconductor junction lasers; 1.55 micron; alloy compositions; band structure; bandgap; electronic structure; energy dispersion relations; epitaxial growth; intervalence band absorption; laser threshold current; optical communications; quantum confinement; semiconductor lasers; strain; valence band; Capacitive sensors; Dispersion; Epitaxial growth; Lead compounds; Optical fiber communication; Photonic band gap; Potential well; Power engineering and energy; Semiconductor lasers; Semiconductor materials;
Journal_Title :
Lightwave Technology, Journal of
