Rate constant for the reaction of CH<sub>3</sub>C(O)CH<sub>2</sub> radical with HBr and its thermochemical implication

Farkas, Edit; Kovács, Gergely; Szilágyi, István; Dóbé, Sándor; Bérces, T.; Márta, F.

doi:10.1002/kin.20135

Cited by 3 publications

(4 citation statements)

References 19 publications

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“…The database of experimental gas-phase rate constants k Br is less extensive and less internally consistent than those for k Cl or k OH , nor do we have the advantage of a compilation of evaluated and recommended values as we had for k Cl and k OH . In addition, because of the lower reactivity of Br•, Arrhenius parameters have typically been obtained at higher temperature and therefore require longer, and questionable, extrapolations to 298 K. A compilation is given in Table . − All formulas have the carbon from which hydrogen abstraction occurs at the beginning followed by the substituents attached, that is, CH 3 X, CH 2 XY, or CHXYZ. For compounds with multiple potential abstraction sites, the experimental rate constant is typically assumed to be dominantly that of the most reactive site, a relatively safe assumption (see below) given the known high selectivity of Br•, compared with, for example, Cl•.…”

Section: Experimental Data Basementioning

confidence: 99%

Extension of Structure–Reactivity Correlations for the Hydrogen Abstraction Reaction by Bromine Atom and Comparison to Chlorine Atom and Hydroxyl Radical

Poutsma

2016

J. Phys. Chem. A

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Recently we presented structure-reactivity correlations for the gas-phase ambient-temperature rate constants for hydrogen abstraction from sp(3)-hybridized carbon by chlorine atom and hydroxyl radical (Cl•/HO• + HCR3 → HCl/HOH + •CR3); the reaction enthalpy effect was represented by the independent variable ΔrH and the "polar effect" by the independent variables F and R, the Hammett constants for field/inductive and resonance effects. Both these reactions are predominantly exothermic and have early transition states. Here, we present a parallel treatment for Br• whose reaction is significantly endothermic with a correspondingly late transition state. Despite lower expectations because the available database is less extensive and much more scattered and because long temperature extrapolations are often required, the resulting least-squares fit (log k298,Br = -0.147 ΔrH - 4.32 ΣF - 4.28 ΣR - 12.38 with r(2) = 0.92) was modestly successful and useful for initial predictions. The coefficient of ΔrH was ∼4-fold greater, indicative of the change from an early to a late transition state; meanwhile the sizable coefficients of ΣF and ΣR indicate the persistence of the "polar effect". Although the mean unsigned deviation of 0.79 log k298 units is rather large, it must be considered in the context of a total span of over 15 log units in the data set. The major outliers are briefly discussed.

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Section: Experimental Data Basementioning

confidence: 99%

Extension of Structure–Reactivity Correlations for the Hydrogen Abstraction Reaction by Bromine Atom and Comparison to Chlorine Atom and Hydroxyl Radical

Poutsma

2016

J. Phys. Chem. A

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“…Interestingly, almost two decades earlier, photoionization mass spectrometric work by Orlov and co-workers, not cited in any of the previous articles, ,− had already flagged a lower value of −41 kJ mol -1 . They reasoned that since replacement of H by methyl generally stabilizes a C-centered radical, this meant that the then-known enthalpies for the reaction could not be reconciled and hence cast doubt on the heat of formation of acetonyl.…”

Section: Introductionmentioning

confidence: 99%

“…Farkas and co-workers used laser-induced fluorescence (LIF) detection of acetonyl in a flow tube to measure the rate at which it H-abstracts from HBr, and from it, they estimate Δ (298 K) = either −24.3 ± 7.5 or −28.1 ± 3.1 kJ mol -1 depending upon much earlier measurements of the reverse reaction 30 or from their own determination of the photobromination of acetone . However, as the authors themselves acknowledge, their results cannot be used to resolve the question because of the fourfold uncertainty in the rate of the reverse reaction.…”

Section: Introductionmentioning

confidence: 99%

Thermochemistry of Acetonyl and Related Radicals

et al. 2006

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Density functional and ab initio calculations at CBS-QB3 levels of theory were employed with a series of isodesmic reactions to determine the thermochemistry of the 2-oxopropyl or acetonyl radical (CH(3)COC*H2). In turn, this was used to determine formation enthalpies of 2-oxoethyl or formylmethyl (C*H(2)CHO), 2-oxobutyl (C*H(2)COC(2)H(5)), 1-methyl-2-oxopropyl or methylacetonyl (C*H(CH(3))COCH(3)), 1-methyl-2-oxobutyl (C*H(CH(3))COC(2)H(5)), and 3-oxopentyl (C*H(2)CH2COC(2)H(5)). Our computed standard enthalpy of formation of -34.9 +/- 1.9 kJ mol-1 and a resonance stabilization energy of approximately 22 kJ mol(-1) for acetonyl are in good agreement with recent re-determinations, which have indicated a substantial lowering in the long-established value for DeltaH(f)o (298.15 K). A bond dissociation energy of 401 kJ mol(-1) is suggested for the C-H bond in acetone with consistent values for the others. The calculations support the enthalpy of formation of acetaldehyde obtained from combustion experiments of -166.1 kJ mol(-1) rather than the figure of -170.7 kJ mol(-1) extracted from enthalpies of reduction and, in addition, serve to reduce the uncertainty in DeltaH(f)o the 2-oxoethyl radical to +13 +/- 2 kJ mol(-1).

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“…Detailed chemical kinetic models have been developed and are readily available for hydrocarbon combustion with some, but far fewer, studies for ketones. Some chemical kinetic models have been developed involving smaller ketones such as for the oxidation of acetone − and several reactions involving acetonyl radicals. − Chemical kinetic models for 2-butanone and 3-pentanone oxidation have recently been reported , where properties for radicals formed from hydrogen abstraction had to be estimated using group additivity and comparisons to acetone. The value used for the secondary carbon–hydrogen bonds was several kcal mol –1 higher than the actual value, and this could affect both unimolecular dissociation and abstraction kinetics in the model.…”

Section: Introductionmentioning

confidence: 99%

Thermochemistry and Bond Dissociation Energies of Ketones

Hudzik

Bozzelli

2012

J. Phys. Chem. A

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Ketones are a major class of organic chemicals and solvents, which contribute to hydrocarbon sources in the atmosphere, and are important intermediates in the oxidation and combustion of hydrocarbons and biofuels. Their stability, thermochemical properties, and chemical kinetics are important to understanding their reaction paths and their role as intermediates in combustion processes and in atmospheric chemistry. In this study, enthalpies (ΔH°(f 298)), entropies (S°(T)), heat capacities (C(p)°(T)), and internal rotor potentials are reported for 2-butanone, 3-pentanone, 2-pentanone, 3-methyl-2-butanone, and 2-methyl-3-pentanone, and their radicals corresponding to loss of hydrogen atoms. A detailed evaluation of the carbon-hydrogen bond dissociation energies (C-H BDEs) is also performed for the parent ketones for the first time. Standard enthalpies of formation and bond energies are calculated at the B3LYP/6-31G(d,p), B3LYP/6-311G(2d,2p), CBS-QB3, and G3MP2B3 levels of theory using isodesmic reactions to minimize calculation errors. Structures, moments of inertia, vibrational frequencies, and internal rotor potentials are calculated at the B3LYP/6-31G(d,p) density functional level and are used to determine the entropies and heat capacities. The recommended ideal gas-phase ΔH°(f 298), from the average of the CBS-QB3 and G3MP2B3 levels of theory, as well as the calculated values for entropy and heat capacity are shown to compare well with the available experimental data for the parent ketones. Bond energies for primary, secondary, and tertiary radicals are determined; here, we find the C-H BDEs on carbons in the α position to the ketone group decrease significantly with increasing substitution on these α carbons. Group additivity and hydrogen-bond increment values for these ketone radicals are also determined.

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Rate constant for the reaction of CH₃C(O)CH₂ radical with HBr and its thermochemical implication

Cited by 3 publications

References 19 publications

Extension of Structure–Reactivity Correlations for the Hydrogen Abstraction Reaction by Bromine Atom and Comparison to Chlorine Atom and Hydroxyl Radical

Extension of Structure–Reactivity Correlations for the Hydrogen Abstraction Reaction by Bromine Atom and Comparison to Chlorine Atom and Hydroxyl Radical

Thermochemistry of Acetonyl and Related Radicals

Thermochemistry and Bond Dissociation Energies of Ketones

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Rate constant for the reaction of CH3C(O)CH2 radical with HBr and its thermochemical implication

Cited by 3 publications

References 19 publications

Extension of Structure–Reactivity Correlations for the Hydrogen Abstraction Reaction by Bromine Atom and Comparison to Chlorine Atom and Hydroxyl Radical

Extension of Structure–Reactivity Correlations for the Hydrogen Abstraction Reaction by Bromine Atom and Comparison to Chlorine Atom and Hydroxyl Radical

Thermochemistry of Acetonyl and Related Radicals

Thermochemistry and Bond Dissociation Energies of Ketones

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Product

Resources

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Rate constant for the reaction of CH₃C(O)CH₂ radical with HBr and its thermochemical implication