Theoretical mechanistic study of the reaction of the methylidyne radical with methylacetylene

A detailed doublet potential energy surface for the reaction of CH with CH₃CCH is investigated at the B3LYP/6-311G(d,p) and G3B3 (single-point) levels. Various possible reaction pathways are probed. It is shown that the reaction is initiated by the addition of CH to the terminal C atom of CH₃CCH, forming CH₃CCHCH 1 (1a,1b). Starting from 1 (1a,1b), the most feasible pathway is the ring closure of 1a to CH₃–cCCHCH 2 followed by dissociation to P ₃ (CH₃–cCCCH+H), or a 2,3 H shift in 1a to form CH₃CHCCH 3 followed by C–H bond cleavage to form P ₅ (CH₂CHCCH+H), or a 1,2 H-shift in 1 (1a, 1b) to form CH₃CCCH₂ 4 followed by C–H bond fission to form P ₆ (CH₂CCCH₂+H). Much less competitively, 1 (1a,1b) can undergo 3,4 H shift to form CH₂CHCHCH 5. Subsequently, 5 can undergo either C–H bond cleavage to form P ₅ (CH₂CHCCH+H) or C–C bond cleavage to generate P ₇ (C₂H₂+C₂H₃). Our calculated results may represent the first mechanistic study of the CH + CH₃CCH reaction, and may thus lead to a deeper understanding of the title reaction.