In-situdiagnostics of hydrocarbon dusty plasmas using quantum cascade laser absorption spectroscopy and mass spectrometry

2014 ◽  
Vol 80 (6) ◽  
pp. 833-841 ◽  
Author(s):  
K. Ouaras ◽  
L. Colina Delacqua ◽  
G. Lombardi ◽  
J. Röpcke ◽  
M. Wartel ◽  
...  
Keyword(s):  
Mass Spectrometry ◽  
Quantum Cascade Laser ◽  
Negative Ions ◽  
Dusty Plasmas ◽  
Qualitative Comparison ◽  
Quantum Cascade ◽  
Laser Absorption ◽  
Electrostatic Probe ◽  
Probe Measurements ◽  
Reaction Characteristic

The formation of carbon nanoparticles in low pressure magnetized H2/CH4and H2/C2H2plasmas is investigated using infrared quantum cascade laser absorption, mass spectrometry, and electrostatic probe measurements. Results showed that dust formation is correlated to the presence of a significant amount of large positively charged hydrocarbon ions. Large negative ions or neutral hydrocarbon were not observed. These results, along with a qualitative comparison of diffusion and reaction characteristic, suggest that a positive ion may contribute to the growth of nanoparticles in hydrocarbon magnetized plasmas.

Characterization of the superlattice region of a quantum cascade laser by secondary ion mass spectrometry

Nanoscale ◽  
2017 ◽  
Vol 9 (44) ◽  
pp. 17571-17575 ◽  
Author(s):  
Paweł Piotr Michałowski ◽  
Piotr Gutowski ◽  
Dorota Pierścińska ◽  
Kamil Pierściński ◽  
Maciej Bugajski ◽  
...  
Keyword(s):  
Mass Spectrometry ◽  
Quantum Cascade Laser ◽  
Secondary Ion Mass Spectrometry ◽  
Quantum Cascade ◽  
Oxygen Contamination ◽  
Ion Mass Spectrometry ◽  
Secondary Ion

Non-uniform oxygen contamination in the superlattice region of a quantum cascade laser measured by secondary ion mass spectrometry.

Quantum-cascade laser absorption spectroscopy for balloon-borne measurements of stratospheric H2O

2021 ◽  
Author(s):  
Simone Brunamonti ◽  
Manuel Graf ◽  
Lukas Emmenegger ◽  
Béla Tuzson
Keyword(s):  
Global Warming ◽  
Absorption Spectroscopy ◽  
Quantum Cascade Laser ◽  
Reference Method ◽  
Laser Absorption Spectroscopy ◽  
Radiative Balance ◽  
Quantum Cascade ◽  
Laser Absorption ◽  
Federal Institute ◽  
Custom Made

<p>Water vapor (H<sub>2</sub>O) is the strongest greenhouse gas in our atmosphere, and it plays a key role in multiple processes that affect weather and climate. Particularly, H<sub>2</sub>O in the upper troposphere - lower stratosphere (UTLS) is of great importance to the Earth's radiative balance, and has a significant impact on the rate of global warming. Hence, accurate measurements of UTLS H<sub>2</sub>O are crucial for understanding and projecting climate. Currently, the reference method used for in-situ measurements of UTLS H<sub>2</sub>O aboard meteorological balloons is cryogenic frostpoint hygrometry (CFH) [1]. However, the cooling agent required for this technique (trifluoromethane) is phasing out as of 2020, due to its strong global warming potential. This represents a major challenge for the continuity of global, long-term stratospheric H<sub>2</sub>O monitoring networks, such as the GCOS Reference Upper Air Network (GRUAN).</p><p>As an alternative to CFH, we developed a compact instrument based on mid-IR quantum-cascade laser absorption spectroscopy (QCLAS) [2]. The spectrometer, with a total weight of 3.9 kg, relies on a segmented circular multipass cell [3] that was specifically developed to meet the stringent requirements, in mass, size and temperature resilience, posed by the harsh environmental conditions of the UTLS. Quick response and minimal interference by H<sub>2</sub>O outgassing from surfaces are achieved by an open-path approach. An elaborate thermal management system ensures excellent internal temperature stability, despite of outside temperature variations of up to 80 K.</p><p>In collaboration with the German Weather Service (DWD), two successful test flights were performed in December 2019 in Lindenberg, Germany. We will report on the results of these test flights, highlighting the instrument outstanding capabilities under UTLS and stratospheric conditions (up to 28 km altitude), and identifying some limitations. Further development activities triggered by the test flights, involving both hardware adaptations and spectral analysis modifications, will be also discussed.  The final validation will be addressed, in cooperation with the Swiss Federal Institute of Metrology (METAS), by laboratory experiments in a custom-made climate chamber, using dynamically generated, SI-traceable reference mixtures with H<sub>2</sub>O amount fractions below 20 ppmv and uncertainty < 1%. The ultimate goal is to demonstrate the potential of QCLAS as a highly valuable technique for quantitative balloon-borne measurements of UTLS and stratospheric H<sub>2</sub>O.</p><p>[1] Brunamonti et al. (2019), J. Geophys. Res. Atmos., doi.org/10.1029/2018JD030000.</p><p>[2] Graf et al. (2020), Atmos. Meas. Tech. Discuss., doi.org/10.5194/amt-2020-243 (Accepted 4 January 2021).</p><p>[3] Graf, Emmenegger and Tuzson (2018), Opt. Lett., doi.org/10.1364/OL.43.002434.</p>

scholarly journals Integrated IR Modulator with a Quantum Cascade Laser

2021 ◽  
Vol 11 (14) ◽  
pp. 6457
Author(s):  
Janusz Mikołajczyk ◽  
Dariusz Szabra
Keyword(s):  
Quantum Cascade Laser ◽  
Quantum Cascade Lasers ◽  
Model Simulation ◽  
Numerical Models ◽  
Spectral Characteristics ◽  
Electrical Performance ◽  
Laboratory Model ◽  
Quantum Cascade ◽  
Laser Absorption ◽  
Direct Laser

This paper presents an infrared pulsed modulator into which quantum cascade lasers and a current driver are integrated. The main goal of this study was to determine the capabilities of a new modulator design based on the results of its electrical model simulation and laboratory experiments. A simulation model is a unique tool because it includes the electrical performance of the lasing structure, signal wiring, and driving unit. In the laboratory model, a lasing structure was mounted on the interfacing poles as close to the switching electronics as possible with direct wire bonding. The radiation pulses and laser biasing voltage were registered to analyze the influence of laser module impedance. Both simulation and experimental results demonstrated that the quantum cascade laser (QC laser) design strongly influenced the shape of light, driving current, and biasing voltage pulses. It is a complex phenomenon depending on the laser construction and many other factors, e.g., the amplitude and time parameters of the supplying current pulses. However, this work presents important data to develop or modify numerical models describing QC laser operation. The integrated modulator provided pulses with a 20–100 ns duration and a frequency of 1 MHz without any active cooling. The designed modulator ensured the construction of a sensor based on direct laser absorption spectroscopy, applying the QC laser with spectral characteristics matched to absorption lines of the detected substances. It can also be used in optical ranging and recognition systems.

Mid-IR Laser Spectrometer for Balloon-borne Lower Stratospheric Water Vapor Measurements

2020 ◽  
Author(s):  
Manuel Graf ◽  
Philipp Scheidegger ◽  
Herbert Looser ◽  
André Kupferschmid ◽  
Thomas Peter ◽  
...  
Keyword(s):  
Water Vapor ◽  
Quantum Cascade Laser ◽  
Environmental Conditions ◽  
Phase Change Materials ◽  
Average Power ◽  
Radiative Balance ◽  
Quantum Cascade ◽  
Laser Absorption ◽  
Federal Institute ◽  
Average Power Consumption

<p>Water vapor is the dominant greenhouse gas, and its abundance in the upper tropospheric/lower stratospheric region (UTLS, 8-25 km altitude) is of great importance to the Earth's radiative balance. Reliable predictions of the climate evolution as well as the understanding of cloud-microphysical processes require the accurate and frequent measurement of water vapor concentrations at these altitudes. The only established method for high-accuracy UTLS water vapor measurements aboard of meteorological balloons is cryogenic frost-point hygrometry (CFH). However, the cooling agent required for its operation (CHF<sub>3</sub>) is to be phased out due to its strong global warming potential. It is, therefore, a major, worldwide challenge to ensure the continuation of the observation of this key Environmental Climate Variable (ECV) of the World Meteorological Organization (WMO). As an alternative method, we present a compact and lightweight instrument based on quantum cascade laser absorption spectroscopy (QCLAS) that reduces systematic errors by contactless and contamination-minimized measurements. Its construction addresses the stringent constraints posed by the harsh environmental conditions found in the UTLS. This is achieved by a fundamental reconsideration of main components of the spectrometer. We developed a highly versatile segmented circular multipass cell (SC-MPC) which supports compact and well-controlled beam folding [1]. The SC-MPC consists of a monolithic aluminum ring with 10.8 cm inner radius, containing 57 quadratic, spherically curved segments, seamlessly shaped into the internal ring surface. The collimated mid-IR beam (λ = 6 µm) from the distributed feedback quantum cascade laser (DFB-QCL) is directly coupled to the MPC without the need for additional beam-shaping optics. This leads to a resilient optical setup suitable for mobile applications and rough environmental conditions. Water vapor amount fractions of <10 ppmv can be measured with a precision better than 1% at 1 Hz. Measuring in open-path mode ensures quick response and minimal interference by water desorbing from surfaces. The instrument weighs less than 4 kg (including battery) and has an average power consumption of 15 W. An elaborate thermal management system that comprises phase change materials and thermoelectric cooling ensures excellent internal temperature stability despite an outside temperature difference of up to 80 K. Specifically developed hard- and software guarantee autonomous operation for the duration of flight [2]. Extensive stability assessments in climate chambers as well as validation experiments using dynamically generated, SI-traceable water vapor mixtures were performed in collaboration with the Swiss Federal Institute of Metrology (METAS). In cooperation with the German Weather Service (DWD) in Lindenberg, the instrument was successfully tested and compared to CFH in two consecutive balloon-ascents in December 2019 up to 28 km altitude, experiencing temperatures and pressures as low as –65°C and 16 hPa, respectively. The drastic reduction in mass and size of a laser absorption-spectrometer and its successful deployment under harshest conditions represents a paradigm change in portable laser spectroscopy and opens the door to previously inaccessible applications.</p><p>[1] Graf, M.; Emmenegger, L.; Tuzson, B. Opt. Lett. 2018, 43, 2434-2437</p><p>[2] Liu, C. et al., L. Rev. Sci. Instrum. 2018, 89 (6), 065107 (9 pp.)</p>

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