The standard procedure to identify the hole- or electron-acceptor character of amorphous organic materials used in OLEDs is to look at the values of a pair of basic parameters, namely, the  ionization potential (IP) and the electron affinity (EA). Recently, using published experimental data, the present authors showed that only IP matters, i.e., materials with IP > 5.7 ( < 5.7) showing electron (hole) acceptor character. Only three materials fails to obey this rule. This work reports ab initio calculations of IP and EA of those materials plus two materials that behave according to that rule, following a route which describes the organic material by means of a single molecule embedded
in a polarizable continuum medium (PCM) characterized by a dielectric constant ε. PCM allows to approximately describe the extended character of the system. This "compound" system was treated within density functional theory (DFT) using several combinations of Functional/Basis set. In the preset work ε it was derived by assuming Koopmans’ theorem to hold. Optimal ε values are in the range 4.4-5.0, close to what is expected for this material family. It was assumed the optical gap to correspond to the excited state with a large oscillator strength among those with the lowest energies, calculated with Time-dependent DFT. Calculated exciton energies were in the range 0.76-1.06 eV, and optical gaps varied from 3.37 up to 4.50 eV. The results are compared with experimental data.