H\"uckel--Hubbard-Ohno modeling of π-bonds in ethene and ethyne with application to trans-polyacetylene

Abstract

Quantum chemistry calculations provide the potential energy between two carbon atoms in ethane (H3C-CH3), ethene (H2C=CH2), and ethyne (HC) as a function of the atomic distance. Based on the energy function for the σ-bond in ethane, Vσ(r), we use the H\"uckel model with Hubbard--Ohno interaction for the π~electrons to describe the energies Vσπ(r) and Vσππ(r) for the σπ double bond in ethene and the σππ triple bond in ethyne, respectively. The fit of the force functions shows that the Peierls coupling can be estimated with some precision whereas the Hubbard-Ohno parameters are insignificant at the distances under consideration. We apply the H\"uckel-Hubbard-Ohno model to describe the bond lengths and the energies of elementary electronic excitations of trans-polyacetylene, (CH)n, and adjust the σ-bond potential for conjugated polymers.