MOLECULAR QUANTUM-CHEMICAL CALCULATIONS OF THE FORMATION OF INTERFACES BETWEEN AL, CA AND MG WITH POLY(PHENYLENE VINYLENE) OLIGOMERS

Molecular quantum chemical calculations were performed both at the ab initio and at the semi-empirical level to model the molecular conforma tions and electronic structure of oligomers of poly(phenylene vinylene ) during the early stages of interface formation with Al, Ca and Mg. W e found that the divalent metals, Mg and Ca, disrupt the conformation of the oligomers less than Al does. The highest occupied molecular orb ital (HOMO) and the lowest unoccupied molecular orbital (LUMO) move in to the energy gap both for Ca- and for Mg-doped systems, resulting in gap-state formation. This is consistent with the polaron/bipolaron pic ture. The electron density plots indicate that the de-localization of electrons is reduced more significantly by Al than it is by Ca and Mg. Our simulation results have been confirmed experimentally via XPS and NEXAFS.