Direct Modulation Characteristics of Composite Resonator Vertical-Cavity Lasers

Author

Grasso, Daniel M. ; Serkland, Darwin K. ; Peake, Gregory M. ; Geib, Kent M. ; Choquette, Kent D.

Author_Institution

Dept. of Electr. & Comput. Eng., Illinois Univ., Urbana, IL

Volume

42

Issue

12

fYear

2006

Firstpage

1248

Lastpage

1254

Abstract

We report the small-signal modulation characteristics of a monolithic dual resonator vertical cavity surface emitting laser. The modulation response is described by a system of rate equations with two independent carrier populations and a single longitudinal optical mode. The independent optical overlaps and differential gains of the two active regions can each be adjusted to maximize the output response. We show that under certain conditions, the composite resonator may achieve a higher bandwidth than a single cavity laser with the same photon density. We find the relaxation oscillation frequency to depend mainly on the total photon density and not the individual currents in the two cavities. With appropriate current injection, the composite resonator laser achieves a maximum -3-dB bandwidth of 12.5 GHz and a maximum modulation current efficiency factor of approximately 5GHz/ma^1/2

Keywords

laser cavity resonators; laser modes; optical modulation; surface emitting lasers; 12.5 GHz; carrier populations; composite resonator laser; current injection; direct modulation; photon density; relaxation oscillation frequency; vertical cavity surface emitting lasers; Bandwidth; Distributed Bragg reflectors; Distributed feedback devices; High speed optical techniques; Masers; Optical feedback; Optical modulation; Optical resonators; Surface emitting lasers; Vertical cavity surface emitting lasers; Composite resonator; coupled cavity; modulation; vertical-cavity laser;

fLanguage

English

Journal_Title

Quantum Electronics, IEEE Journal of

Publisher

ieee

ISSN

0018-9197

Type

jour

DOI

10.1109/JQE.2006.883499

Filename

4015584