Abstract
AbstractQuantum chemical method (CCSD(T)/cc‐pVTZ//M06‐2X/6‐311++G(d,p)) is employed to research the CF3CBrCH2 + OH reaction. The results indicate that the reaction takes place through the interaction of the oxygen atom of the OH radical with the middle C and terminal C atom of CF3CBrCH2 generating adduct IM1 (CF3CBrCH2OH) and IM2 (CF3CBrOHCH2), respectively, and then further dissociation or rearrangement to many products. The rate constants have been computed at 10−10 to 1010 Torr and 200–3000 K by RRKM theory for various product pathways. The results show that at 200–800 K, the rate constant for the production of IM1 (CF3CBrCH2OH) by collisional deactivation is dominant; at high temperatures, the production of P1 (CF3CBrCHOH + H) becomes predominate. The predicted data for CF3CBrCH2 + OH agree closely with available experimental value. The total rate constants are independent on pressure and dependent on temperature. The rate equation can be fitted as k(T) = 1.77 × 10 −7T−0.65exp(−4518.77/T) at 200–300 K, 30 Torr of Ar. The atmospheric lifetime of CF3CBrCH2 in OH is around 2.77 days. TD‐DFT computations imply that IM1, IM2, IM3, IM4, IM5, and IM6 will photolyze under the sunlight.
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