Theoretical gain of strained-layer semiconductor lasers in the large strain regime

Author

Chong, Tow C. ; Fonstad, Clifton G.

Author_Institution

Dept. of Electr. Eng. & Comput. Sci., MIT, Cambridge, MA, USA

Volume

25

Issue

2

fYear

1989

Firstpage

171

Lastpage

178

Abstract

The theoretical gain of strained-layer semiconductor lasers is analyzed in the large strain regime based on the density-matrix method, taking into account the modification of both the valence bands and the transition dipole moments. The wave functions for the valence-band states for an arbitrary wave vector at the Gamma point in the presence of stain are derived from diagonalization of the strain Hamiltonian using the original wave functions obtained from the k-p method. These wave functions are then used to obtain the dipole moment matrix elements at the band edges, which are found to be independent of the wave vector.<>

Keywords

laser theory; semiconductor junction lasers; valence bands; wave functions; Gamma point; density-matrix method; dipole moment matrix elements; k-p method; strain Hamiltonian; strained-layer semiconductor lasers; transition dipole moments; valence bands; wave functions; Anisotropic magnetoresistance; Capacitive sensors; Gallium arsenide; Laser theory; Laser transitions; Optical polarization; Semiconductor lasers; Substrates; Tellurium; Wave functions;

fLanguage

English

Journal_Title

Quantum Electronics, IEEE Journal of

Publisher

ieee

ISSN

0018-9197

Type

jour

DOI

10.1109/3.16260

Filename

16260