Simultaneous vibrational, rotational, and translational thermometry based on laser absorption of co in shock-induced non-equilibrium

Abstract

A mid-infrared laser absorption strategy for measuring translational, rotational, and vibrational temperatures of carbon monoxide (CO) simultaneously at high speeds was developed for application to high temperature non-equilibrium 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 in argon bath gas mixtures 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 4.98 μm and an external cavity quantum cascade laser was used to probe the R-branch transition near 4.37 μm. The sensing strategy 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, 0.03–0.4 atm), including behind incident shock waves traveling up to 3.3 km/s. Measured temperature results were compared to equilibrium and non-equilibrium simulations.