On the stabilization energy of α-methoxyalkyl radicals

The resonance stabilization energies, Es, of polyenyl radicals can be estimated by the equation E,(N) = -13.2+ [ 3.95 -15.8 (2) -2/n] kcal mol -I, where N is the number of C, C-x bonds in the polyenyl radicals. This correlation has been extended for predicting the weakest H-C, C-C and C-OH bond diss

## Abstract The conformational space of dipeptide models derived from glycine, alanine, phenylalanine, proline, tyrosine, and cysteine has been searched extensively and compared with the corresponding C~α~ dipeptide radicals at the G3(MP2)‐RAD level of theory. The results indicate that the (least‐s

## Abstract The thermolysis reactions of 3a and 2a, b were studied over a temperature range of 40°C and the activation parameters were determined. They were compared with the activation parameters of structurally comparable hydrocarbons of similar strain in order to obtain the radical stabilization

We have been prompted to investigate the effects of a-substituents on the inversion barriers of radicals 1 by the large difference in configurational stability between the unsubstituted cyclopropyl radicalA and an a-fluorocyclopropyl radical.3 We report here our results on the inversion rates of an