Conformational studies of substituted five-membered cyclic carbonates and related compounds by MNDO, and the X-ray crystal structure of 4-chlorophenyloxymethyl-l,3-dioxolan-2-one

Abstract

Geometries, torsional barriers, and dipole moments have been computed for mono-, di-, tri-, and tetra-substituted five-membered cyclic carbonates and for some substituted cyclopentanones, oxolanes, 4-butyrolactones, and 1,3-dioxolanes. With respect to cyclic carbonates it was deduced that the potential curve increases moderately with T₃₄₅₆(torsion angle) and for most compounds a 1 kcal difference between ⁴T₅ or ⁵T₄ conformers and planar form corresponds to a torsional angle of ±14–16°. The minimum is, in general, flattened and close to planar. Additional modes of ring, puckering such as ⁵E, E₅, ⁴E, E₄ and ²E, E₂ were also examined. Between the enantiomeric structures with opposite distortions, the quasi equatorial conformation of the alkyl group is preferred.

endo and exo anomeric effects in carbonate systems have been studied by introducing strong electron-withdrawing substituents, in the carbonate 4-position. The exo anomeric effect was observed with many of the polar substituents, but the role of the anomeric effect in ring puckering (endo effect) was found to be small.

For other five-membered ring systems MNDO predicts that the energy barrier to interconversion of planar ↔ twist is in the following order: carbonates > 1,3-dioxolanes > butyrolactones > oxolanes > cyclopentanones.

N.m.r data are also included as well as the single-crystal X-ray diffraction study of 4-chlorophenyloxymethyl-1,3-dioxolan-2-one.