J. Morin, Y. Bedjanian
Mar 1, 2017
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Journal
Journal of Analytical and Applied Pyrolysis
Abstract
Abstract Thermal decomposition of n-propyl (C3H7ONO2, PPN) and n-butyl (C4H9ONO2, BTN) nitrates has been studied in a low pressure flow reactor combined with a quadrupole mass spectrometer. The rate constants of the nitrates decomposition were measured as a function of pressure (0.95–12.8 Torr of helium) and temperature in the range 473–659 K using two different approaches: from kinetics of nitrate loss and those of the formation of the reaction products. The fit of the observed falloff curves with two parameter expression k = k 0 k ∞ [ M ] k 0 [ M ] + k ∞ × 0.6 ( 1 + ( log ( k 0 [ M ] k ∞ ) ) 2 ) − 1 provided the following low and high pressure limits for the rate constants of the nitrates decomposition: k0(PPN) = 0.68 × 10−4 exp(−15002/T) cm3molecule−1 s−1, k∞ (PPN) = 7.34 × 1015 exp(−19676/T) s−1, k0(BTN) = 2.80 × 10−4 exp(−15382/T) cm3molecule−1 s−1 and k∞(BTN) = 7.49 × 1015 exp(−19602/T) s−1, which allow to reproduce (via above expression and with 20% uncertainty) all the experimental data obtained for the rate constants of PPN and BTN decomposition in the temperature and pressure range of the study. It was observed that the initial step of the thermal decomposition of the nitrates is O NO2 bond cleavage leading to formation of NO2 and alkoxy radical, which rapidly decomposes or isomerizes to form C2H5 and formaldehyde and C3H7, CH2O and hydroxybutyl radical as final products of PPN and BTN decomposition, respectively. In addition, the kinetic data were used to determine the O NO2 bond dissociation energy of 38.0 ± 1.2 and 37.8 ± 1.0 kcal mol−1 in PPN and BTN, respectively.