The rate constant for the reaction C 2 H 4 + H ⇔ C 2 H 3 + H 2 was studied behind reflected shock waves at temperatures between 1619 and 1948 K and pressures near 10 atm in a mixture of C 2 H 4 , CH 4 , H 2 , and argon. C 2 H 4 time histories were measured using laser absorption of a CO 2 gas laser near 10.53 μm. Experimental mixtures were designed to optimize sensitivity to the title reaction with only weak sensitivity to secondary reactions. Two mechanisms, FFCM1 and ARAMCO v2, are used for data analysis. The well-selected operating conditions and Monte Carlo sampling data analysis procedure resulted in mechanism-independent reaction rate constant measurements with a 2σ uncertainty of ±35%. The current data disagree with a broadly used theoretical calculation (Knyazev et al. (1996)), but they are in good consensus with one of the review studies (Baulch et al. (2005)), k = (3.9 × 10 22 ) T 3.62 exp(−5670/T) cm 3 molecule −1 s −1 . To the best of our knowledge, this work provides the first high-temperature study of the C 2 H 4 + H ⇔ C 2 H 3 + H 2 reaction rate constant with well-defined uncertainty.
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