High-performance GaAs/AlAs terahertz quantum-cascade lasers for spectroscopic applications

Terahertz (THz) quantum-cascade lasers (QCLs) based on GaAs/AlAs heterostructures have been developed for application-defined emission frequencies between 3.4 and 5.0 THz. These THz QCLs can be used as local oscillators in airborne or satellite-based astronomical instruments or as radiation sources for high-resolution absorption spectroscopy. The GaAs/AlAs THz QCLs can be operated in mechanical cryocoolers and even in miniature mechanical cryocoolers due to their comparatively high wall-plug efficiency of around 0.2% and typical current densities below 500 A/cm2. These lasers exhibit output powers of more than 1 mW at operating temperatures up to about 70 K, which is sufficient for most of the abovementioned applications.

(Top) Compilation of operating parameters of 21 GaAs/AlAs QCLs (asterisks) fabricated from 11

different wafers. The maximum output powers of Fabry-Pérot lasers based on single-plasmon

waveguides are shown for continuous-wave operation as a function of the emission frequency. The vertical dashed lines indicate the target frequencies of 3.36, 3.55, 3.92, and 4.75 THz. The blue solid line depicts a simulated transmission spectrum of air based on the HITRAN database for ambient conditions corresponding to the USA model, mean latitude, summer, and an optical path length of 10 m, exhibiting maxima at 3.43, 4.32, and 4.92 THz. (Bottom) Maximum output power under continuous-wave operation as a function of heatsink temperature for a laser with ridge dimensions of 0.08 × 0.87 mm2 emitting at 4.75 THz operated in a Stirling cooler. The dashed line indicates the power of 1 mW as a guide to the eye. The corresponding practical operating temperature, for which the output is at least 1 mW, amounts to 72 K.

Due to their narrow line width and rather large intrinsic tuning range, QCLs for the THz spectral region are promising radiation sources for high-resolution spectroscopy of molecules, atoms, and ions utilizing rotational or fine-structure transitions. In atmospheric science, the rotational transition of the hydroxyl radical (OH) at 3.55 THz and the fine-structure line of atomic oxygen (OI) at 4.75 THz are of particular interest. Both can be measured with QCL-based heterodyne receivers. For fundamental research and industrial applications, high-resolution absorption spectroscopy based on fine-structure transitions in Al, N+, and O at 3.36, 3.92, and 4.75 THz, respectively, is expected to allow for the quantitative determination of the atom and ion densities in plasma processes. Furthermore, QCLs emitting in the atmospheric windows around 3.43, 4.32, and 4.92 THz are of interest for applications if the THz radiation has to be transmitted through air over a longer distance up to about 10 m.


Starting from recently developed GaAs/AlAs QCLs for 4.75 THz with a wall plug efficiency which is by a factor of 3 larger than the one for corresponding GaAs/Al0.25Ga0.75As QCLs, the layer structure of this design was gradually scaled toward lower or higher frequencies. The target frequencies for the gain maxima are achieved by an appropriate adjustment of the quantum well thicknesses and a corresponding fine-tuning of the thicknesses of some particular barriers. Although the growth of the QCLs with very thin AlAs barriers remains challenging, the operating parameters of 21 lasers fabricated from 11 different wafers have been analyzed. The output powers of Fabry-Pérot lasers based on single-plasmon waveguides reach values of up to 6 mW at an operating temperature of 30 K. The threshold current densities vary between 100 and 300 A/cm2. Optimized lasers exhibit competitive wall plug efficiencies and emission powers of more than 1 mW at rather high operating temperatures in continuous-wave operation. For 4.75 THz, we demonstrated an output power of more than 1 mW for an operating temperature larger than 70 K using laser ridge dimensions of 0.08 × 0.87 mm2 when operated in a mechanical cryocooler.


1 Autor L. Schrottke , X. Lü , B. Röben , K. Biermann , T. Hagelschuer , M. Wienold , H.-W. Hübers , M. Hannemann , J.-P. H. van Helden , J. Röpcke , H. T. Grahn

High-performance GaAs/AlAs terahertz quantum-cascade lasers for spectroscopic applications

Source IEEE Trans. Terahertz Sci. Technol. , 10 , 133 ( 2019 )
DOI : 10.1109/TTHZ.2019.2957456 | 3129 Cite : Bibtex RIS
L. Schrottke, X. Lü, B. Röben, K. Biermann, T. Hagelschuer, M. Wienold, H.-W. Hübers, M. Hannemann, J.-P. H. van Helden, J. Röpcke, and H. T. Grahn