Change of the molecular surface and volume during internal rotation and its effect on conformational equilibrium in solution

Abstract

Conformational dependence of the molecular surface S and molecular volume V for hexane and 1,1,2-trichloroethane during rotation around a central bond in the molecules have been calculated. A model of overlapping spheres is used, the size of the spheres being determined by Van der Waals radii of individual atoms. Plots of S and V against torsional angle φ are compared with the potential of internal rotation of both molecules E(φ). The calculated molecular surfaces and volumes of the two molecules for the most stable conformers mutually differ by several percent as experimental results also indicate. We also show that the differences in S and V between individual conformers always affect conformational equilibrium in solution even if solvent-solute interaction energies are not explicitly considered. As a consequence of the mentioned volume changes during internal rotation in a molecule, the conformational energies for hydrocarbons in the condensed and gaseous phases can differ by as much as several kJ mol −1.