Evaluation of Material Systems for THz Quantum Cascade Laser Active Regions

Detz, Hermann; Andrews, A. M.; Kainz, Martin A.; Schönhuber, Sebastian; Zederbauer, Tobias; MacFarland, Donald; Krall, Michael; Deutsch, C.; Brandstetter, Markus; Klang, P.; Schrenk, W.; Unterrainer, K.; Strasser, G.

doi:10.1002/pssa.201800504

Cited by 12 publications

(6 citation statements)

References 56 publications

(90 reference statements)

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“…1,29 Figure 1(c) shows scanning electron microscopy (SEM) and transmission electron microscopy (TEM) images of an MIR QCL, in which the periodic nature of the growth can be clearly seen. To date, best performance has been obtained with four semiconductor material systems: 156 GaInAs/ AlInAs grown on InP substrates; GaAs/AlGaAs grown on GaAs substrates; AlSb/InAs grown on InAs substrates; and InGaAs/AlInAsSb, InGaAs/GaAsSb, or InGaAs/AlInGaAs grown on InP substrates. The choice of the material system affects the intersubband gain, the shortest possible wavelength of operation dictated by the conduction band, and the location of the Reststrahlen bands.…”

Section: Quantum Cascade Lasers: Principles Of Operation and Modelingmentioning

confidence: 99%

“…The choice of the material system affects the intersubband gain, the shortest possible wavelength of operation dictated by the conduction band, and the location of the Reststrahlen bands. 3,155,156 The intrinsic (quantum noise limited) linewidth of QCLs is subkilohertz, around 500 Hz for MIR QCLs and around 100 Hz for THz QCLs. [30][31][32][33][34] Practical instantaneous linewidths are around 10 kHz, and on the order of tens of megahertz over longer time-scales.…”

Section: Quantum Cascade Lasers: Principles Of Operation and Modelingmentioning

confidence: 99%

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Sensing and imaging using laser feedback interferometry with quantum cascade lasers

Rakić

Taimre

Bertling

et al. 2019

Applied Physics Reviews

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Quantum cascade lasers (QCLs) are high-power sources of coherent radiation in the midinfrared and terahertz (THz) bands. Laser feedback interferometry (LFI) is one of the simplest coherent techniques, for which the emission source can also play the role of a highly-sensitive detector. The combination of QCLs and LFI is particularly attractive for sensing applications, notably in the THz band where it provides a high-speed high-sensitivity detection mechanism which inherently suppresses unwanted background radiation. LFI with QCLs has been demonstrated for a wide range of applications, including the measurement of internal laser characteristics, trace gas detection, materials analysis, biomedical imaging, and near-field imaging. This article provides an overview of QCLs and the LFI technique, and reviews the state of the art in LFI with sensing using QCLs.

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Section: Quantum Cascade Lasers: Principles Of Operation and Modelingmentioning

confidence: 99%

Section: Quantum Cascade Lasers: Principles Of Operation and Modelingmentioning

confidence: 99%

Sensing and imaging using laser feedback interferometry with quantum cascade lasers

Rakić

Taimre

Bertling

et al. 2019

Applied Physics Reviews

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“…Designs with improved LO-phonon-assisted depopulation process via a double extraction mechanism or a double-phonon resonant depopulation have been realized. Heterostructures with higher barriers for reduced carrier leakage were studied. , Alternative material systems to GaAs/AlGaAs, with lower effective electron mass, are promising because the optical gain in the heterostructure scales inversely to the effective mass. , Such materials include InGaAs/InAlAs, , InGaAs/AlGaInAs, − InGaAs/GaAsSb, and InAs/AlAsSb with material compositions lattice matched to InP and InAs, respectively. The first three material systems suffer from very thin barriers and interface roughness effects but show already good results with maximum operation temperatures of 155 K and output powers up to 600 mW in pulsed operation .…”

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confidence: 99%

Barrier Height Tuning of Terahertz Quantum Cascade Lasers for High-Temperature Operation

et al. 2018

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Terahertz quantum cascade lasers (QCLs) are excellent coherent light sources, but are still limited to an operating temperature below 200 K. To tackle this, we analyze the influence of the barrier height for the identical three-well terahertz QCL layer sequence by comparing different aluminum concentrations (x = 0.12–0.24) in the GaAs/AlxGa1-xAs material system, and then we present an optimized structure based on these findings. Electron injection and extraction mechanisms as well as LO-phonon depopulation processes play crucial roles in the efficient operation of these lasers and are investigated in this study. Experimental results of the barrier height study show the highest operating temperature of 186.5 K for the structure with 21% aluminum barriers, with a record kBTmax/ℏω value of 1.36 for a three-well active region design. An optimized heterostructure with 21% aluminum concentration and reduced cavity waveguide losses is designed and enables a record operating temperature of 196 K for a 3.8 THz QCL.

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“…A variety of materials and approaches are employed in order to improve the performance of QCLs [7,25], and this must be underpinned by a good understanding of carrier transport within these devices. The dominant material system for THz QCLs is GaAs/AlGaAs due to its performance and technology level, however great interest is drawn by semiconductors with lower effective masses as InGaAs and InAs [26,27] or higher longitudinal optical (LO) phonon energy such as GaSb and GaN [25,28] and reliable and efficient modelling approaches are needed for further development of THz technology.…”

Section: Introductionmentioning

confidence: 99%

Prospects of temperature performance enhancement through higher resonant phonon transition designs in GaAs-based terahertz quantum-cascade lasers

et al. 2022

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In this work we discuss terahertz quantum cascade laser designs that employ resonant phonon mechanism to assist the lasing process. We investigate whether the higher energy separation would be more beneficial for high temperature performance than commonly used resonant value of 36 meV (in GaAs). We show that our density matrix model can be used for reliable cut–off temperature estimation and we present design improvement of several exemplary structures by enhancing their material gain to attain 10 - 50 K higher cut–off temperature

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Evaluation of Material Systems for THz Quantum Cascade Laser Active Regions

Cited by 12 publications

References 56 publications

Sensing and imaging using laser feedback interferometry with quantum cascade lasers

Sensing and imaging using laser feedback interferometry with quantum cascade lasers

Barrier Height Tuning of Terahertz Quantum Cascade Lasers for High-Temperature Operation

Prospects of temperature performance enhancement through higher resonant phonon transition designs in GaAs-based terahertz quantum-cascade lasers

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