A THEORETICAL AND EXPERIMENTAL INVESTIGATION OF THE ELECTRONIC-STRUCTURE OF ALPHA-FE2O3 THIN-FILMS

Ground and excited states of alpha-Fe2O3 have been investigated by determining the spin polarized wavefunctions and eigenvalues of an embedded Fe2O912- cluster using the discrete variational X(alpha) method. The computed transition energies compare reasonably well with the recorded experimental spectrum of high-purity alpha-Fe2O3 thin films obtained by the sol-gel technique. The theoretical data herein reported predict a very high valence-conduction band gap incompatible with the experimental outcomes, which were routinely interpreted as originated by an interband transition. In contrast to this, the lowest-energy optical transitions have a charge transfer nature, involving excitation of electrons from the occupied O 2p-based spin down levels to the empty Fe atom-like spin down orbitals.