DocumentCode
755348
Title
Bound-to-continuum and two-phonon resonance, quantum-cascade lasers for high duty cycle, high-temperature operation
Author
Faist, Jérôme ; Hofstetter, Daniel ; Beck, Mattias ; Aellen, Thierry ; Rochat, Michel ; Blaser, Stéphane
Author_Institution
Inst. de Phys., Neuchatel Univ., Switzerland
Volume
38
Issue
6
fYear
2002
fDate
6/1/2002 12:00:00 AM
Firstpage
533
Lastpage
546
Abstract
Recent advances in quantum-cascade (QC) laser active-region design are reviewed. Based on a rate equation model of the active region, we show why new gain regions. based on a two-phonon resonance or a bound-to-continuum transition exhibit significantly better performance than the traditional design based on a three-quantum-well active region. Threshold current densities as low as 3 kA/cm2 at T=300 K, operation with a peak power of 90 mW at 425 K, single-mode high-power operation up to temperatures above 330 K at λ≈16 μm and continuous wave operation up to T=311 K are demonstrated. QC lasers able to operate at high duty cycles (50%) on a Peltier cooler were used in a demonstration of a 300-MHz free-space optical link between two buildings separated by 350 m
Keywords
infrared sources; infrared spectroscopy; laser theory; laser transitions; optical communication equipment; phonon-phonon interactions; population inversion; quantum well lasers; resonant tunnelling; spectroscopic light sources; 16 micron; 300 K; 311 K; 330 K; 425 K; 90 mW; Peltier cooler; active-region design; bound-to-continuum transition; electron extraction bottleneck; free-space optical link; high duty cycles; high-temperature operation; injection efficiency; laser transition; lattice matched layers; population inversion; quantum-cascade laser; radiative transition; rate equation model; short wavelength devices; single-mode high-power operation; threshold current densities; tunneling time; two-phonon resonance; Equations; Laser modes; Laser transitions; Optical design; Performance gain; Quantum cascade lasers; Resonance; Temperature; Thermoelectric devices; Threshold current;
fLanguage
English
Journal_Title
Quantum Electronics, IEEE Journal of
Publisher
ieee
ISSN
0018-9197
Type
jour
DOI
10.1109/JQE.2002.1005404
Filename
1005404
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