DocumentCode
1451632
Title
Successful Application of the 8-band
Theory to Optical Properties
Author
Fujisawa, Takeshi ; Sato, Tomonari ; Mitsuhara, Manabu ; Kakitsuka, Takaaki ; Yamanaka, Takayuki ; Kondo, Yasuhiro ; Kano, Fumiyoshi
Author_Institution
NTT Photonics Labs., Atsugi, Japan
Volume
45
Issue
9
fYear
2009
Firstpage
1183
Lastpage
1191
Abstract
Band-edge optical properties of highly strained In(Ga)As/InGaAs quantum wells on InP with the bandgap wavelength longer than 2 mum are analyzed by using 6- and 8-band kmiddotp theory. It is demonstrated that the 8-band model is indispensable for the analysis of highly strained In(Ga)As/InGaAs quantum wells due to the strong coupling between conduction and valence bands induced by large strain in the well. Furthermore, an energy correction originating from the interaction between the spin-orbit coupling and the strain, which has been discarded in conventional kmiddotp theory, is taken into account, and the role of the effect for highly strained quantum wells is discussed. The photoluminescence peak wavelength and absorption spectra of In(Ga)As/InGaAs quantum wells calculated by 8-band model are in excellent agreement with those obtained by experiment, showing the validity of the results presented here.
Keywords
III-V semiconductors; conduction bands; gallium arsenide; indium compounds; k.p calculations; photoluminescence; semiconductor quantum wells; spin-orbit interactions; valence bands; 8-band kmiddotp theory; InAs-InGaAs; InGaAs; conduction-valence band coupling; optical properties; photoluminescence peak wavelength; quantum wells; spin-orbit coupling; Absorption; Capacitive sensors; Effective mass; High speed optical techniques; Indium gallium arsenide; Indium phosphide; Laser theory; Optical coupling; Photoluminescence; Quantum mechanics; ${mbi{k}} {cdot} {mbi{p}}$ theory; Band structure; microscopic theory; quantum well lasser; strained quantum well;
fLanguage
English
Journal_Title
Quantum Electronics, IEEE Journal of
Publisher
ieee
ISSN
0018-9197
Type
jour
DOI
10.1109/JQE.2009.2021776
Filename
5257377
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