Abstract
A new scheme, called “list of nonredundant bonds”, is presented to record the number of bonds and their
positions for the atoms involved in Kekulé valence structures of (poly)cyclic conjugated systems. Based on this scheme, a
recursive algorithm for generating Kekulé valence structures has been developed and implemented. The method is general
and applicable for all kinds of (poly)cyclic conjugated systems including fullerenes. The application of the algorithm
in generating Valence Bond (VB) wave functions, in terms of Kekulé valence structures, is discussed and illustrated in
actual VB calculations. Two types of VBSCF calculations, one involving Kekulé valence structures only and the second
one involving all covalent VB structures, were performed for benzene, pentalene, benzocyclobutadiene, and naphthalene.
Both strictly local and delocalised p-orbitals were used in these calculations. Our results show that, when the orbitals are
restricted to their own atoms, other VB structures (Dewar structures) also have a significant contribution in the VB wave
function. When removing this restriction, the other VB structures (Dewar and also the ionic structures) are accommodated
in the Kekulé valence structures, automatically. Therefore, at VBSCF delocal level, the ground states of these systems
can be described almost quantitatively by considering Kekulé valence structures only at a considerable saving of time.
Original language | English |
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Pages (from-to) | 696-708 |
Number of pages | 13 |
Journal | Journal of Computational Chemistry |
Volume | 32 |
Issue number | 4 |
DOIs | |
Publication status | Published - 2010 |