Synthetic and structural studies of [6]-, [7]- and [10]metacyclophanes

Abstract

A new preparative sequence from 2,3-polymethylene-2-cyclopentenone 5 to 2,6-polymethylenebromobenzenes 3 (n = 6, 7, 10) and 2,6-polymethylenephenyllithiums 6 has been found. The reaction of 6 with various electrophiles produces a number of new compounds to disclose the unique reactivity of the aryl C-Li moiety surrounded by the polymethylene chain. Photolysis of 3a and 3b provides transannular products 8, 10 and 11, all arising from the proximity between the aromatic bromine and the aliphatic hydrogen intraannularly opposed to be removed as HBr. Spectrometric study gives quantitative data of the dependence of the molecular geometry upon the chain length and the aromatic substituents. The energy barriers ΔG c ≠ of the conformational flipping are 17·4 kcal/mol (T c 76·5°) for [6]metacyclophane ( 7a), 11·5 kcal/mol (T c −28°) for [7]metacyclophane ( 7b), ·8 kcal/mol for [10]metacyclophane ( 7c). The lower-energy process of the aliphatic chain in [6]metacyclophane derivatives is the pseudorotation with substituent-dependent barrier ΔG c ≠ 11·1 kcal/mol (T c −31·5°) for 7a, 12·4 kcal/mol (T c −4·5°) for 3a and 12·7 kcal/mol (T c 1·0°) for 12a. The rather large rotational barrier is attributed to the compressed structure of each system. The benzene ring distortion of the cyclophanes is deduced from the bathochromic shift of the B-band and the diamagnetic shift of the benzene proton signals in the PMR.