Substrate and positional selectivity in electrophilic substitution reactions in pyrrole, furan, thiophene, and selenophene derivatives and related benzoannelated systems

Data on the relative reactivities (substrate selectivity) of five-membered heterocycles in electrophilic substitution reactions and positional selectivity (alpha : beta ratio) in these reactions were analyzed. Unlike the substrate selectivity (pyrrole >> furan > seletiophene > thiophene) determined by the position of heteroatoms in the Periodic Table, the positional selectivity decreases in the order corresponding to the change in the relative stability of the onium states of the elements (O+ < Se+ <= S+ < N+) and reflects the predominant role of heteroatoms in the stabilization of a complexes formed upon P-substitution. These differences in the positional selectivity of the parent heterocycles have a substantial effect on the orientation in electrophilic substitution reactions in their derivatives and the corresponding benzoannelated systems. This interpretation was confirmed by ab initio quantum chemical calculations (RHF/6-31G(d) and MP2/6-31G(d)//RHF/6-31G(d)) and density functional theory calculations (B3LYP/6-31G(d)). Quantum chemical calculations were performed by the above-mentioned methods for model N-R-pyrroles (R = Me, Et, Pr-i, Bu-t, CH=CH2, C equivalent to CH, Ph, PhSO2, and 4-O2NC6H4) and their (alpha- and beta-protonated a complexes. The results of these calculations demonstrated that it is the steric factors and charges on the beta-C, alpha-C, and N atoms and the substituents at the N atom (the kinetic control), as well as the nature of the electrophile, rather than the difference in-the relative stabilities of the onium states of N+ (which depends on the nature of the substituent at the N atom and reflects the role of the heteroatom in stabilization of a complexes formed via beta-substitution; the thermodynamic control) that are responsible for the type of orientation (alpha or beta) that prevails.