Abstraction of chlorine atoms from chloroalkanes. III. The kinetics of liquid phase reactions of trichlorosilyl radicals with chloromethanes

The kinetics of chlorine atom abstraction from the chloromethanes (ClM), CCl₄, CHCl₃, CH₂Cl₂, and CH₃Cl by radiolytically generated trichlorosilyl radicals was studied in the liquid phase by a competitive method. Arrhenius parameters of chlorine atom abstraction from chloromethanes relative to that of bromine atom abstraction from cyclohexyl bromide (RBr) were as follows: The error limits are two standard deviations (2σ) from least mean square Arrhenius plots. From the linear correlation between E_cl values derived from the reactions of SiCl₃ and cyclohexyl radicals with the ClM series it is estimated that E_cl (R + CH₃Cl) ? 16 kcal/mole. In addition the relative Arrhenius parameters for the hydrogen atom abstraction from SiHCl₃ and chlorine atom abstraction from CCl₄ by cyclohexyl radicals were obtained log A_H/A_cl = 0.12 ± 0.15 and E_H ? E_cl = 0.24 ± 0.26. The E_H ? E_cl value was combined with existing data on E(R + CCl₄) to yield the E_H(R + SiHCl₃) value.     

Kinetic study of gas-phase reactions with CF2Cl2 and CFCl3. Analysis using the transition state theory (TST) of the chlorine atom transfer reactions by CF3 and CH3 radicals from halomethanes

The following gas-phase reactions: were studied by the competitive method with CF₃I as the source of radicals. The kinetic parameters obtained in the temperature range 533–613 K and 503–613 K respectively for chlorine atom transfer reactions are given by: where θ = 2.303 RT (cal mol^?1). The Arrhenius A values were calculated for seven chlorine atom transfer reactions (CF₂Cl₂, CFCl₃, CCl₄ with CF₃ radicals; CF₃Cl, CF₂Cl₂, CFCl₃ and CCl₄ with CH₃ radicals) by using the thermochemical kinetic version of the Transition State Theory (TST).     

Abstraction of chlorine atoms from chloromethanes by the cyclohexyl radical

The kinetics of chlorine atom abstraction from the chloromethanes (CM)CCl₄, CHCl₃, and CH₂Cl₂ by radiolytically generated cyclohexyl radicals has been studied in the liquid phase by a competitive method. The halogen abstraction data have been put on an absolute basis by comparing the rates of the metathetical reactions with the known rate of addition of cyclohexyl radicals to C₂Cl₄. The following Arrhenius parameters were obtained:

The reactions of methyl radicals with chloromethanes

The reaction of methyl radicals with CCl₄ and CCl₃Br have been reinvestigated in the gas phase over a wide range of temperatures and pressures using both the photolysis of acetone and the pyrolysis of di-tertiary butyl peroxide (dtBP) as the methyl radical sources. The results are in essential agreement with previous work; however, these new studies provide evidence that at higher pressures the major source of HCl in the reactions is due to methyl radical attack on CH₃CCl₃, formed via the combination of methyl and trichloromethyl radicals. From these investigations Arrhenius parameters for the reactions have been determined: Pyrolysis of dtBP in the presence of relatively high-pressure mixtures of CCl₄ and CCl₃Br resulted in no enhanced methane formation, since, under these conditions, the only termination product is C₂Cl₆, and the HCl precursor CH₃CCl₃ is not formed. A competitive technique has been used in which dtBP was pyrolysed in the gas phase in the presence of high-pressure mixtures of CCl₃Br and a chloromethane. Arrhenius parameters were obtained for the reactions and the results were used to provide information on the importance of polar effects for hydrogen abstraction from halogenated methanes.     

Abstraction of chlorine atoms from chloroalkanes. V. The liquid-phase reaction between Et3SiH radicals and CH2Cl2, CHCl3, CCl4, and CCl3CN

The kinetics of chlorine transfer from CH₂Cl₂, CHCl₃, CCl₄, and CCl₃CN to the triethylsilyl radical was studied in the liquid phase by a competitive method. Br abstraction from 1-bromopentane was used as a reference. The following Arrhenius parameters were determined: where the error limits are two standard deviations (2σ). Based on these results, the observed reactivity trends in the chlorine transfer reactions of Et₃Si radicals appear to primarily reflect the variation in entropy of activation rather than in activation energies.     

Abstraction of chlorine atoms from polychloroethanes. IV. The kinetics of chlorine abstraction from 1,1,2-trichloroethane, 1,1-dichloroethane,and 1,2-dichloroethane by cyclohexyl radicals

The kinetics of chlorine atom abstraction from the chloroethanes (EClH) 1,1,2-C₂Cl₃H₃, 1,1-C₂Cl₂H₄, and 1,2-C₂Cl₂H₄ by radiolytically generated cyclohexyl radicals was studied in the liquid phase by a competitive method. The chlorine atom abstraction data were put on an absolute basis by comparing the rates of the metathetical reactions with the known rate of addition of cyclohexyl radicals to C₂Cl₄. The following Arrhenius parameters were obtained:

The reaction of cyclopentyl radicals with carbon tetrachloride

The photolysis of azocyclopentane in the presence of cyclopentane–carbon tetrachloride mixtures has been investigated in the gas phase. Product analysis data have been used to determine the Arrhenius parameters for the reactions The rate data for chlorine atom abstraction from CCl₄ by the cyclopentyl radical were compared with available data for other alkyl radicals in both the gas and the solution phases. The results indicate that the rate constant for chlorine atom abstraction in the gas phase is fairly insensitive to the nature of the attacking alkyl radical and that the activation energy for a secondary radical is about 4 kcal/mol higher than the corresponding reaction in the solution phase.     

Effect of cyano group substitution on metathetical reactions. IV. Substituent effects on the rates of cyanomethyl radical reaction with haloalkanes

Gamma radiation-induced free radical chain reactions in liquid mixtures of BrCH₂CN, eyelohexane (RH), and haloalkanes (XCCl₃) were studied. The kinetics of hydrogen and chlorine atom abstraction from CHCl₃, CH₃CCl₃, CH₂ClCCl₃, CHCl₂CCl₃, CF₃CCl₃, C₂Cl₆, CCl₃CN, and CCl₄ by CH₂CN radicals were investigated by a competitive method. The reactions investigated were Rate constant ratios k₃/k₂, k₅/k₆, k₇/k₂, and k₃/k₇ were determined at 180°C. In the CCl₄? RH? BrCH₂CN system k₃/k₂ was determined in the temperature range of 100–180°C, yielding log k₂ k₃ = ?0.11 ± 0.2 ?(3.34 ± 0.39/θ): where θ = 2.3RT in kcal/mol. The value E₂? E₃ was combined with existing data on E₃ to yield E₂(CCl₄) = 17.57 kcal/mol. The reactivity trend of CH₂CN is compared with that of R radicals. It is shown that in spite of a difference of about four orders of magnitude in k_Cl values, the reactive cyclohexyl radical is somewhat more selective than CH₂CN. It is proposed that the relative reactivities log[k₂(XCCl₃)/k₂(CH₃CCl₃)] can be correlated in terms of a dual-parameter Taft equation which takes into account both resonance and inductive substituent effects.     

Photolysis of carbon tetrachloride in the presence of alkanes

The photolysis of carbon tetrachloride in the presence of a number of alkanes has been investigated in the gas phase. The products obtained from the photolysis experiments were those expected from a chain reaction in which trichloromethyl radicals abstract hydrogen atoms from the alkane. The data have been used to determine Arrhenius parameters for hydrogen abstraction from the series of alkanes CH₄, C₂H₆, C₃H₈, and i-C₄H₁₀ by trichloromethyl radicals, The rate data obtained are used to explain why termination reactions involving alkyl radicals become less significant as the alkane becomes more complex.     

Radiation-induced dechlorination of carbon tetrachloride in cyclohexane and n-hexane mixtures. III. The kinetics of liquid-phase reactions of trichloromethyl radicals

The kinetics of gamma-radiation-induced free-radical chain reactions in solutions of carbon tetrachloride in mixtures of varying composition of cyclohexane and n-hexane was investigated in the temperature range of 296°–413°K. Trichloromethyl radicals were produced by the reaction of radiolytically generated alkyl radicals with the solute. The kinetics of the following reactions were studied: The following rate expression was obtained: The error limits are the standard deviation from the least mean-square Arrhenius plots. The present results, combined with previously measured activation parameters for hydrogen-atom abstraction from c-C₆H₁₂ and n-C₆H₁₄ by CCl₃ radicals relative to CCl₃ combination, afford experimental evidence that the decay of trichloromethyl species in alkane solutions is a diffusion-limited process. The thesis that activation energies of reactions (4) and (5) in the liquid phase are equal to their respective values in the gas phase is confirmed.     

Some hydrogen abstraction reactions of the CF3CCl2 radical

The gas phase photolysis of CF₃CCl₃ in the presence of several alkanes has been used to obtain Arrhenius parameters for the abstraction of hydrogen atoms by the CF₃CCl₂ radical: Activation energies of 9.6 and 8.0 kcal/mole are found for abstraction from secondary and tertiary C–H bonds, respectively. The Arrhenius parameters are compared to those for CCl₃ and CF₃ radicals.     

Cl-atom transfer from CFCl3 to the c-C6H11 radical. An indirect estimation of the CFCl2?Cl bond dissociation energy

The Cl-transfer reaction between CFCl₃ and c-C₆H₁₁ radicals (R) was studied in liquid cyclohexane (RH). The Arrhenius parameters for Cl abstraction were determined in the RH-CFCl₃ system versus the termination reaction between cyclohexyl radicals and competitively versus addition to C₂Cl₄ in the RH-CFCl₃-C₂Cl₄ system. The two sets of results are in very good agreement and give the following Arrhenius expression for the reaction R + CFCL₃ → RCl + CFCl₂ (2): where θ = 2.303RT in kcal/mol. Comparison with Cl-transfer data of other chloromethanes and chloroethanes shows that an increase in the C? Cl bond dissociation energy is the main cause of the reduced reactivity of CFCl₃. Based on a previously developed correlation, D(CFCl₂ ? Cl) is estimated to be equal to 74.4 kcal/mol.     

Relative rate constants for the reactions of trichloropropenyl radical. Application of the two-parameter Taft equation

The relative rate constants for the hydrogen atom abstraction by CCl₃CH?CH· radical from CH₂Cl₂, CHCl₃, CH₃COCH₃, CH₃CN, C₆H₅CH₃, C₆H₅OCH₃, CH₃CHO, and CH₃OH in the liquid phase at 20°C have been measured. It was shown that these reaction rate constants are correlated by the two-parameter Taft equation with ρ* = 0.726 ± 0.096, r* = 1.22 ± 0.16. A relationship between r* and bond dissociation energy D(R? H) has been found for the abstraction reactions of different free radicals.     

Correlation of activation energies of radical–molecule metathesis reactions with enthalpic,polar, and steric parameters

It is shown that the activation energies E oF chlorine atom abstraction by cyclohexyl radicals and hydrogen atom abstraction by Cl atoms from polychloroalkanes can be correlated with the bond dissociation energies D and the Taft polar and steric substituent constants σ* and E_s by the expression: where ΔE and ΔD represent the differences between the E and D values of a given substrate and those of a reference compound (CH₃ substituted substrate) and α, ρ, and δ are the corresponding correlation coefficients. The use of this expression allows quantitative evaluation of the relative contribution of the various factors affecting the activation energies of these reactions and estimation of related thermochemical data.     

The reaction of cyclohexyl radicals with carbon tetrachloride

The photolysis of azocyclohexane, carbon tetrachloride, and cyclohexane at 360 nm has been investigated over a wide temperature range. At moderate temperatures a chain reaction ensues from which the following approximate rate constants could be determined assuming 2CCl₃. → C₂Cl₆, k₅ = 10^9.7 (303–673K): The really striking feature of the results is that they show that termination in bicyclohexyl [reaction (7)] is extremely slow: The root-mean-square rule for estimating the cross-combination rate is also followed. The photolysis of carbon tetrachloride and cyclohexane at 250 nm has also been investigated. The reaction is complicated by the occurrence of two concurrent photolytic processes, the main one yielding trichloromethyl radicals and chlorine atoms, and the subsidiary one yielding dichlorocarbene and molecular chlorine. Nonetheless the results from this reaction can be interpreted in the medium temperature range 360–430K, where long chains are present, in terms of the rate constants derived from the azocyclohexane system.     

An evaluation of the kinetic parameters for the reaction of trifluoromethyl radicals with CH3Cl in the gas phase in the temperature range from 416 to 636 K

The hydrogen and chlorine atom abstraction reactions from CH₃Cl by CF₃ radicals produced by the photolysis of hexafluoroacetone (HFA) and CF₃I were studied relative to the recombination of CF3 radicals (I) The Arrhenius parameters obtained in the temperature range 416 to 578 K are: where Θ = 2,303.RT cal mol^?1 and k₂ is the recombination rate constant for the CF₃ radicals. The factors that influence the transfer processes of chlorine and hydrogen are analyzed in a series of reactions of halomethanes with CF₃ and CH₃ radicals. © 1993 John Wiley & Sons, Inc.     

Gas phase reaction of heptafluoroisopropyl radicals with carbon tetrachloride

The reaction was investigated in the gas phase over the range 80–225°C using the photolysis of heptafluoroisopropyl iodide as the source of radicals. The rate constant, based on the value of 10^13.36 cm³ mol^?1 s^?1 for the recombination of i-C₃F₇ radicals, is given by where θ = 2.303 RT/cal mol^?1. Arrhenius parameters for chlorine abstraction from CCl₄ by CF₃, C₂F₅, n-C₃F₇, and some hydrogenated radicals are compared.     

Organic Phosphorus Compounds 59. A new method for the synthesis of phosphonic dichlorides

Heating of thiophosphonic dichlorides, RP(S)Cl₂, R ? CH₃, C₂H₃, C₂H₅, with a molar equivalent of SOCl₂ under pressure at 150° for 5 to 8 h yields phosphonic dichlorides in quantitative yield. In addition sulfur and sulfur dichloride is formed according to the equation: This method is particularly useful for the preparation of CH₃P(O)Cl₂ since it was observed that chlorination of CH₃P(O)(OCH₃)₂ with PCl₅ yields CH₃OP(O)Cl₂ as a by-product which is difficult to separate from CH₃P(O)Cl₂. On the other hand chlorination of methylphosphonic acid with PCl₅ also gives pure CH₃P(O)Cl₂ .     

Rearrangement with 1,2-migration of chlorine in reaction of p-methylbenzyl radicals with 3,3,3-trichloropropene

Conclusions The reaction of p-xylene with 3,3,3-trichloropropene, initiated by peroxides, leads to the formation of 1,1-dichloro-4-(p-tolyl)-1-butene, 1,1,2-trichloro-4-(p-tolyl)butane, and 1,1-dichloro-2-chloromethyl-3-(p-tolyl)propane, which testifies to a rearrangement of the CCl₃HCH₂CH₂C₆H₄CH₃ radicals to the C1₂CHCI-CH₂ CH₂C₆H₄CH₃ radicals with the 1,2-migration of chlorine.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 9, pp. 2122–2124, September, 1976.