Numerical analysis of static wavelength shift for DFB lasers with longitudinal mode spatial hole burning

Author

Yamanaka, Takayuki ; Seki, Shunji ; Yokoyama, Kiyoyuki

Author_Institution

NTT Opto-Electron. Labs., Kanagawa, Japan

Volume

3

Issue

7

fYear

1991

fDate

7/1/1991 12:00:00 AM

Firstpage

610

Lastpage

612

Abstract

The static wavelength shift induced by longitudinal mode spatial hole burning is analyzed numerically for lambda /4-shifted DFB lasers. The effective Bragg wavelength at each bias level is introduced to clarify the contribution of nonuniformity in carrier density distribution to the lasing wavelength shift. It is shown that the wavelength shift is caused by two separate factors: by the position-dependent deviation and by the average value in the exact N/sub eq/ distribution. The former factor induces both red- and blue-shifted tuning due to the nonuniformity itself in carried density distribution, while the latter results in blue-shifted tuning due to the increase in modal gain.<>

Keywords

distributed feedback lasers; laser modes; laser theory; laser tuning; optical hole burning; semiconductor junction lasers; spectral line shift; bias level; blue-shifted tuning; carrier density distribution; diode lasers; effective Bragg wavelength; lambda /4-shifted DFB lasers; lasing wavelength shift; longitudinal mode spatial hole burning; modal gain; red-shifted laser tuning; static wavelength shift; Charge carrier density; Laser modes; Laser transitions; Laser tuning; Lead compounds; Numerical analysis; Plasma density; Plasma waves; Semiconductor lasers; Steady-state;

fLanguage

English

Journal_Title

Photonics Technology Letters, IEEE

Publisher

ieee

ISSN

1041-1135

Type

jour

DOI

10.1109/68.87929

Filename

87929