The dissociative ionization of methyl fluoride. The formation of CH2+ and CH3+

The kinetics of the gas-phase reaction of CH3F with 12 have been studied spectrophotometrically from 629 to 710 K, and were determined to be consistent with the following mechanism: (KIJ squares analysis of the kinetic data taken in the initial stages of reaction resulted in log k4 (M-w) = (11.3 f

## Photoionization mass spectrometry was used to investigate the dynamics of ion-neutral complex-mediated dissociations of the Iz-pentane ion (1). Reinterpretation of previous data demonstrates that a fraction of ions 1 isomerizes to the 2-methylbutane ion (2) through the complex [CHaCH+CHa'CH,CH,

It is concluded that C3H80+' formed by dissociation of ionized 2ethoxyethanol ( ) is a mixture of CH,CH,OCHl' (7) and 'GH,+OHCH,CH, (2). Formation of 7 and CH3CH2+0HCH3 ( ) is attributed to dissociations of species formed by the hydrogen transfers [ CH,CH20CH2+ 'CH,OHI + [CH,CH,OCHi' CH,Ol -+ [CH,CH

An analysis of thermochemical and kinetic data on the bromination of the halomethanes CH, ,X,, (X = F, C1, Br; n = 1-31, the two chlorofluoromethanes, CH,FCI and CHFCl,, and CH,, shaws that the recently reported heats of formation of the radicals CH2C1, CHClz, CHBr2, and CFC12, and the C-H bond diss

The structures ofcthylidcne and propylidene in their lowest singlet states :ue considered using INDO lnd MIND 112 calculations. Using a gadicnt optimization method, it is found that R!INDO/Z predicts no encrg minimu.n f-or singlet ethylidenc, while INDO predicts non-&ssic4 bridged structures for the