Photodissociation of 1,2-chloroiodoethane at 248 and 266 nm: The enthalpy of formation of CH2ClCH2I

Abstract

The technique of photofragmentation translational spectroscopy has been utilized to study the photodissociation of CH₂ClCH₂I at excitation wavelengths of 248 and 266 nm. The primary photofragments are C₂H₄Cl and either I*(²P_1/2) or I(²P_3/2). A fraction of the chloroethyl radical product contains enough internal excitation after the primary process to undergo secondary dissociation into C₂H₄ and Cl. By observing the threshold for this secondary process, the reaction enthalpy for CH₂ClCH₂I→C₂H₄+Cl+I was determined, which leads to: ΔH⁰_f,0 (CH₂ClCH₂I)=−7.8±1 kcal/mol. The c. m. translational energy distribution of the photofragments was derived for both the I* and I channels, yielding I*/I branching ratios of 1.5 at 248 nm and 3 at 266 nm. The translational energy distribution also revealed that about 50% of the excess energy went into translation. The angular distributions of dissociation products with respect to the laser polarization indicate that the primary photodissociation process for the ground and excited state iodine channels at both wavelengths proceeds via a parallel transition, i.e., the transition moment must be nearly parallel to the C–I bond.