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Nonequilibrium Vibrational, Rotational, and Translational Thermometry via Megahertz Laser Absorption of CO

Christopher Jelloian, Fabio A. Bendana, Chuyu Wei, R. Mitchell Spearrin, Megan E. MacDonald

2021Journal of Thermophysics and Heat Transfer29 citationsDOI

Abstract

A mid-infrared laser absorption strategy for simultaneously measuring translational, rotational, and vibrational temperatures of carbon monoxide (CO) at high speeds was developed for application to high-temperature nonequilibrium environments relevant to Mars atmosphere entry. Rapid-tuning scanned wavelength techniques were used to spectrally resolve the R(0,66), P(0,31), P(2,20), and P(3,14) lines of the CO fundamental vibrational bands at a rate of 1 MHz to infer multiple temperatures of CO behind incident and reflected shock waves in a shock tube. A distributed feedback quantum cascade laser was used to probe the P-branch transitions near and an external cavity quantum cascade laser was used to probe the R-branch transition near , both using bias-tee circuitry. The sensing method is shown to resolve each targeted transition with temporal and spectral resolution sufficient for quantitative multi-temperature measurements over a wide range of temperatures and pressures (2100–5500 K, 0.03–1.02 atm), including behind incident shock waves traveling up to 3.3 km/s. Measured temperature results were compared to equilibrium and nonequilibrium simulations.

Topics & Concepts

LaserMaterials scienceQuantum cascade laserNon-equilibrium thermodynamicsShock tubeCascadeAbsorption (acoustics)Shock waveShock (circulatory)OpticsAtomic physicsInfraredWavelengthPhysicsChemistryThermodynamicsInternal medicineMedicineChromatographySpectroscopy and Laser ApplicationsGas Dynamics and Kinetic TheoryAtmospheric and Environmental Gas Dynamics
Nonequilibrium Vibrational, Rotational, and Translational Thermometry via Megahertz Laser Absorption of CO | Litcius