Laser-based CO concentration and temperature measurements in high-pressure shock-tube studies of n-heptane partial oxidation

This paper presents a laser-based absorption technique for measuring temperature and CO concentration in high-pressure shock tubes. Two fundamental vibrations of CO ( v " = 0, P8, 4.73 µm and v " = 1, R21, 4.56 µm) were selected for high-temperature sensitivity with a reduced influence fro...

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Bibliographic Details
Published in:Applied physics. B, Lasers and optics Lasers and optics, 2020, Vol.126 (8), Article 142
Main Authors: He, Dong, Nativel, Damien, Herzler, Jürgen, Jeffries, Jay B., Fikri, Mustapha, Schulz, Christof
Format: Article
Language:English
Subjects:
Absorption
Applied physics
Broadband
Burnout
Engineering
Heptanes
High temperature
Laser applications
Lasers
Optical Devices
Optics
Oxidation
Photonics
Physical Chemistry
Physics
Physics and Astronomy
Pressure broadening
Quantum cascade lasers
Quantum Optics
Reaction kinetics
Shock tubes
Time measurement
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Summary:This paper presents a laser-based absorption technique for measuring temperature and CO concentration in high-pressure shock tubes. Two fundamental vibrations of CO ( v " = 0, P8, 4.73 µm and v " = 1, R21, 4.56 µm) were selected for high-temperature sensitivity with a reduced influence from pressure broadening compared to previous work. Single-pass absorption (80 mm path length) was measured with two quantum-cascade lasers. The technique was demonstrated by measuring time-resolved temperature for non-reactive mixtures at 1100–1960 K and 1.2–9.7 bar. During partial oxidation of n -heptane, temperature and CO concentrations were measured with 4 µs time resolution at 1360–1670 K and 5.8–8.2 bar. Interference from broadband CO 2 absorption was quantified and subtracted. Measured data in the burnout state are in excellent agreement with predictions from kinetics mechanisms (Mehl et al. Proc Combust Inst 33:193, 2011; Zhang et al. Combust Flame 172:116, 2016) over the entire range of operating conditions, which validates the performance of the current laser-absorption technique in reactive-mixture measurements. Additionally, time-resolved temperature and CO-concentration measurements agree well with predictions based on the Mehl et al. mechanism.
ISSN:0946-2171
1432-0649
DOI:10.1007/s00340-020-07492-7