Abstract

The rates of initiation of neopentane pyrolysis over the temperature range 756–845 K have been measured at reactant pressures in the range 100–200 Torr, by processing of data relating to the formation of the termination product, ethane, using an exact algebraic procedure. Thus, the data are free of the ambiguities introduced by the empirical extrapolation procedures used in previous direct determinations of the initial rates and the derived Arrhenius parameters of neo–C5H12→ CH3+ t–C4H9. (1) The result obtained is log (k1/s–1)= 16.1 ± 1.0 –(330 ± 15 kJ mol–1)/2.303 RT. Values of k1 are in agreement with previously measured values but the Arrhenius parameters are inconsistent with the presently accepted thermochemistry of reaction (1). A modified thermochemistry for the t-butyl radical is proposed leaving the heat capacity unchanged but using the new values for 298 K, ΔHf/kJ mol–1= 39, S(1 mol cm–3)/J mol–1 K–1= 210.8. These, and the presently derived k1 values allow the calculation for 800 K of log (k–1/cm3 mol–1S–1)= 12.9 with essentially zero activation energy and hence, via the geometric mean rule, lead to log (k9/cm3 mol–1 s–1)= 11.9 for the mutual recombination reaction, 2t–C4H9→ 2,2,3,3-tetramethylbutane. (9)The new thermochemistry suggested for t-butyl reconciles most thermochemically calculated values of k9 with directly measured values over a wide temperature range. However, further experimental and theoretical justification is necessary before the new thermochemistry can be unequivocally accepted.Concurrently evaluated with k1 is the result log (k3k6/k5/cm3 mol–1 s–1)= 13.2 ± 1.5 –(127 ± 12 kJ mol–1)/2.303 RT CH3+ neo–C5H12→ CH4+ C5H11(3), CH3+ i–C4H8→ CH4+ C4H7(6), 2CH3→ C2H6(5) which is shown to be in excellent agreement with that calculated from the independent results of other workers.

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