Formation, structure and conformational dynamics of highly substituted diphenylcarbonates

Abstract

The symmetrical carbonates 5-8 were prepared from ethyl 4-hydroxybenzoates with aryl-, 4-(arylethynyl)-phenyl-, arylethynyl- or arylbutadiynyl-substituents in the 3- and 5-positions, by reaction with triphosgene. The choice of base (pyridine, DMAP, NaH) had a strong influence on the conversion: For the synthesis of the carbonates 5 and 6, it was sufficient to use pyridine as the base. However, for the synthesis of the carbonates 7 and 8, NaH had to be used instead. Single-crystal X-ray structure analysis of these carbonates revealed that the substituents point towards the corners of a distorted tetrahedron with the carbonate group sitting in the middle of the tetrahedron and the two angular phenolic building blocks intersecting with an angle of 51-71 degrees. In solution at room temperature, all four substituents are magnetically equivalent as a consequence of conformational flexibility. The two enantiomeric conformers of carbonate 5a interconvert rapidly, probably via a perfect trans conformation with the plane of the Aralpha perpendicular to the carbonate plane. In the case of carbonates 6-8 this process is inhibited by unfavourable interaction of the long substituents at the benzoate moiety. The dynamic process, which has an energy barrier of 8-10 kcalmol(-1), is described in a simplified manner as a continuous rotation of the angular building blocks around the carbonate unit with the C(aryl)-O bonds as the axes of rotation.