Gas-Phase Photolysis of Methyl Iodide. Reactions of Hot Methyl Radicals with Added Organic Compounds

Abstract

The photolysis of CH₃I and CD₃I at 2537 and 3130 Å has been investigated in the presence of CD₃CH₃, C₂D₆, CH₃CD₂CH₃, CD₃CH₂CD₃, C₄H₁₀–C₄D₁₀ (1:1) mixtures, (CH₃)₃CD, (CH₃)₃CCD₃, C₆H₆, C₆H₁₂, CH₃OCH₃, CH₃COOCD₃, CD₃OH, C₂D₅OH, and CD₃CH₂OH. All mixtures were saturated with iodine in order to prevent the formation of methane by the reaction of thermal methyl radicals. It is shown that, under these conditions, the measured quantum yield of methane formation can be considered to be the probability that a ``hot'' methyl radical with 32 kcal will react with CH<sub>3</sub>I or the additive. The following observations were made: (1) Intramolecular and intermolecular isotope effects are of minor importance. (2) The probability of abstraction of an H or a D atom from a molecule by a ``hot'' methyl radical increases with the number of available H or D atoms, or with a decrease in the ΔH of the reaction. For instance, it is seen that the relative probabilities per atom for abstraction of a primary, secondary, or tertiary H atom in a hydrocarbon molecule are 1:3.6:10.0. A variation in wavelength, from 2537 Å to 3130 Å, lowers the methane quantum yield by a factor of 10 but does not greatly affect the relative probabilities of abstraction from different sites within a molecule. (3) The quantum yield of methane in the photolysis of CH₃I or CH₃I—hydrocarbon mixtures is nearly twice that observed for CD₃I or the corresponding CD₃I—hydrocarbon mixtures at the same wavelength. It is concluded that systematic studies of this type may prove to be useful in determining a priori the probability of reaction with other related organic compounds.