CORRELATION-EFFECTS ON THE BAND-GAP OF CONDUCTING POLYMERS

By applying the projection technique to the computation of excitation energies, we study the correlation effects on the band gap of conducting polymers. In the presence of an additional electron or hole, the correlation induces a polarization cloud around the additional particle, which forms a polaron. For the excitation energy of a polaron, there is a competition between a loss of the correlation energy in the ground state and a gain of polarization energy. For the Hubbard interaction, the loss of correlation energy is dominant and correlations increase the band gap. However, for long-range interactions, the gain of polarization energy is dominant and correlations decrease the band gap. Screening the long-range interaction suppresses the gain of the polarization energy so that correlations again increase the band gap. A small dimerization is always favorable to the correlation effects. For trans-polyacetylene, we obtain the on-site repulsion U = 4.4 eV and the nearest-neighbor interaction V = 0.8 eV. The screening of pi electrons due to the polarizability of sigma electrons is quite strong.