Mechanism of thermal energy charge transfer reactions: + N2. Analysis of isotopic data

ICR s~ctroscopy hns been used to reinvest&ate the He' f Nz cherge txnsfcr r\*.L g3,1ction zt thermal en~+p rlJLrs. It is con- cluded that zt least 60% of the N' come from short lived exckd (N:j\*.

The km&c energy released in near-thermal charge-transfer reactions of Ar\* and NC with NO, 0,. CO, H,O, N,O. CO, and NH, has been measured. The partitioning between kinetic and inlemal modes is found lo be very similar for mosl 01 the Ar+/N: pan-s. Tko hypotheses LO explain tis similarity are propos

Charge-transfer reactions of Ar+ with CH,Cl,\_, (n= l-3) at thermal energy have been studied by using a flowing-afterglow apparatus coupled with a low pressure chamber. Dissociative charge-transfer leading to CH: (91 k 5%) CH&l+ (95 k 2%), and Ccl+ (69 f 3%) are major product channels for CH,Cl, CH#

\(\mathrm{N}_{2}^{+}\left(\mathrm{B}^{2} \Sigma_{\mathrm{u}}^{+}-\mathrm{X}^{2} \Sigma_{\mathrm{g}}^{+}\right)\)emission was observed from the near-resonant charge transfer between \(\mathrm{Ne}_{2}^{+}\)and \(\mathrm{N}_{2}\). Vibrational populations for \(v^{\prime}=0\) and 1 of \(N_{2}^{+}(B)\) w