Cavity-Volume Scaling Law of Quantum-Dot Metal-Cavity Surface-Emitting Microlasers

Quantum-dot (QD) metal-cavity surface-emitting microlasers are designed, fabricated, and characterized for various sizes of cavity volume for both lateral and vertical confinements. Microlasers using submonolayer QDs in the active region are fabricated according to our design model optimized for a r...

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Bibliographic Details
Published in:IEEE photonics journal 2012-08, Vol.4 (4), p.1103-1114
Main Authors: Matsudaira, Akira, Lu, Chien-Yao, Zhang, Meng, Chuang, Shun Lien, Stock, Erik, Bimberg, Dieter
Format: Article
Language:English
Subjects:
Cavity resonators
Distributed Bragg reflectors
Nanocavities
nanolasers
Nanostructures
plasmonics
Plasmons
Quantum dot lasers
surface-emitting lasers
Vertical cavity surface emitting lasers
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Summary:Quantum-dot (QD) metal-cavity surface-emitting microlasers are designed, fabricated, and characterized for various sizes of cavity volume for both lateral and vertical confinements. Microlasers using submonolayer QDs in the active region are fabricated according to our design model optimized for a resonant metal cavity. The cavity-volume scaling law is studied by our theoretical modeling and experimental demonstration. The smallest laser has a diameter of 1 \mu\hbox{m} with silver metal cladding operating at room temperature with electrical injection in pulsed mode. Our experimental results show significant self-heating effect in the smaller devices with a diameter of a few micrometers due to high series resistance and high threshold gain. With the use of hybrid metal-DBR mirrors, the number of DBR pairs in the top hybrid mirror can be reduced from 19.5 to 5.5 without sacrificing threshold current density.
ISSN:1943-0655
1943-0647
DOI:10.1109/JPHOT.2012.2202315