Charge Transport Properties of Tris(8-hydroxyquinolinato)aluminum(III): Why It Is an Electron Transporter

Abstract

The charge transport properties of mer-tris(8-hydroxyquinolinato)aluminum(III) (mer-Alq), which is the most widely used electron transport material in OLED, were investigated by quantum chemistry calculations within the framework of the charge hopping model and Marcus electron transfer theory. Internal reorganization energies of 0.276 and 0.242 eV were calculated by the DFT-B3LYP method employing a 6-31 G* basis set for the electrons λ_i(e) and holes λ_i(h), respectively. The relative distances and orientations of Alq molecules in amorphous film were simulated by those in the β-phase. The intermolecular charge-transfer integrals, H_da(h) and H_da(e), along all 14 hopping pathways were then calculated by the Koopmans Theorem in conjunction with the Hartree−Fock method employing a 6-31 G* basis set as well as by the direct coupling method. The results showed that there were some H_da(e) that were 1 order of magnitude larger than any H_da(h), because hopping pathways with effective overlaps of LUMOs can occur and, thus, large H_da(e). On the other hand, effective overlap of HOMO was absent in all pathways, resulting in a relatively small H_da(h). This difference in the magnitudes of H_da(e) and H_da(h) would predict a 2 orders of magnitude difference in the electron-transfer rate constants and account for the observed 2 orders of magnitude difference in the mobilities of electrons and holes.