Abstract
The conversion of
phenylcarbene (1) into fulvenallene (17) and ethynylcyclo-pentadiene (18) on
gas-phase pyrolysis has been examined by 13C-tracer techniques.
Complete randomization of all seven carbon atoms has been shown to precede ring
contraction. The result is consistent with a pool of intermediates
[cycloheptatrienylidene (19) and bicyclo[4,1,0]hepta-2,4,6-triene (21)],
interconverting rapidly through tautomerism and concomitant H-shifts.
Dimerization, intramolecular trapping, and ring contraction constitute the
major exits from this pool. ��� Gas-phase thermolysis of indazole generates
the same products (17)/(18) and in this case the mechanism has been
investigated by the intramolecular trapping in 1-deutero-3-methylindazole to
yield deuterostyrenes. Two pathways are revealed, proceeding respectively
through phenylcarbene and 2-methylene-3,5-cyclohexadienyl-idene (36); factors
affecting the latter pathway are discussed.
Cited by
32 articles.
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