Abstract
Theoretical studies were conducted on the predicted gas and solution phase thermodynamic properties for isomerisation of various [1.1]paracyclophane derivatives to their corresponding transannular[4+4] adducts at representative levels of density functional and composite method theories. Calculations suggest that the [1.1]paracyclophane to transannular[4+4] adduct isomerisations are not likely amenable to thermodynamic solvent tuning for the methylene, ether and thioether-bridged derivatives using a broad range of nonpolar and polar aprotic and polar protic implicit solvation models, but may be receptive towards solvent tuning for the amine-bridged analogues. Varying the nature of the cyclophanic bridging atoms and the electron-withdrawing/releasing character of photochemically/thermally stable substituents on the π-systems is predicted to facilitate substantial variation of the isomerisation equilibria to a much greater degree than changing the solvent environment.
Acknowledgements
This work was made possible by the facilities of the Western Canada Research Grid (WestGrid: www.westgrid.ca; project 100185), the Shared Hierarchical Academic Research Computing Network (SHARCNET: www.sharcnet.ca; project sn4612) and Compute/Calcul Canada.