Detail publikačního výsledku
Evaluation of Material Systems for THz Quantum Cascade Laser Active Regions
DETZ, H.; ANDREWS, A.; KAINZ, M.; SCHÖNHUBER, S.; ZEDERBAUER, T.; MACFARLAND, D.; KRALL, M.; DEUTSCH, C.; BRANDSTETTER, M.; KLANG, P.; SCHRENK, W.; UNTERRAINER, K.; STRASSER, G.
Originální název
Evaluation of Material Systems for THz Quantum Cascade Laser Active Regions
Anglický název
Evaluation of Material Systems for THz Quantum Cascade Laser Active Regions
Druh
Článek WoS
Originální abstrakt
Quantum cascade lasers (QCLs) have been realized in several different material systems. In the mid-infrared, active regions are predominantly based on In0.53Ga0.47As and InAs as quantumwellmaterial. Market-ready devices routinely provide continuous-wave operation at room temperature. For their THz counterparts, the situation is less clear. The most common material system for THz QCLs is the inherently lattice-matched combination of GaAs with Al0.15Ga0.85As barriers. Yet, these devices still only reach a maximum operating temperature of 200 K with a lack of progress within the past years. Based on the identification of key parameters, this work reviews material systems for quantum cascade lasers with an emphasis on material and growth-related aspects and the goal to identify promising candidates for future device generations. Similar active regions realized in different material systems allow to estimate the gain per unit thickness, as well as total growth times and relative thickness errors.
Anglický abstrakt
Quantum cascade lasers (QCLs) have been realized in several different material systems. In the mid-infrared, active regions are predominantly based on In0.53Ga0.47As and InAs as quantumwellmaterial. Market-ready devices routinely provide continuous-wave operation at room temperature. For their THz counterparts, the situation is less clear. The most common material system for THz QCLs is the inherently lattice-matched combination of GaAs with Al0.15Ga0.85As barriers. Yet, these devices still only reach a maximum operating temperature of 200 K with a lack of progress within the past years. Based on the identification of key parameters, this work reviews material systems for quantum cascade lasers with an emphasis on material and growth-related aspects and the goal to identify promising candidates for future device generations. Similar active regions realized in different material systems allow to estimate the gain per unit thickness, as well as total growth times and relative thickness errors.
Klíčová slova
III–V heterostructures, intersubband devices, molecular beam epitaxy, quantum cascade lasers, superlattices
Klíčová slova v angličtině
III–V heterostructures, intersubband devices, molecular beam epitaxy, quantum cascade lasers, superlattices
Autoři
DETZ, H.; ANDREWS, A.; KAINZ, M.; SCHÖNHUBER, S.; ZEDERBAUER, T.; MACFARLAND, D.; KRALL, M.; DEUTSCH, C.; BRANDSTETTER, M.; KLANG, P.; SCHRENK, W.; UNTERRAINER, K.; STRASSER, G.
Rok RIV
2019
Vydáno
26.09.2018
ISSN
1862-6300
Periodikum
PHYSICA STATUS SOLIDI A-APPLICATIONS AND MATERIALS SCIENCE
Svazek
1
Číslo
1
Stát
Spolková republika Německo
Strany od
1
Strany do
8
Strany počet
8
URL
BibTex
@article{BUT150301,
author="Hermann {Detz} and Aaron M. {Andrews} and Martin A. {Kainz} and Sebastian {Schönhuber} and Tobias {Zederbauer} and Donald {MacFarland} and Michael {Krall} and Christoph {Deutsch} and Martin {Brandstetter} and Pavel {Klang} and Werner {Schrenk} and Karl {Unterrainer} and Gottfried {Strasser}",
title="Evaluation of Material Systems for THz Quantum Cascade Laser Active Regions",
journal="PHYSICA STATUS SOLIDI A-APPLICATIONS AND MATERIALS SCIENCE",
year="2018",
volume="1",
number="1",
pages="1--8",
doi="10.1002/pssa.201800504",
issn="1862-6300",
url="https://onlinelibrary.wiley.com/doi/full/10.1002/pssa.201800504"
}