Lattice Relaxation and Charge-Transfer Optical Transitions Due to Self-Trapped Holes in Non-Stoichiometric LaMnO3 Crystal

Abstract

We use the Mott-Littleton approach to evaluate polarisation energies in LaMnO3 lattice associated with holes localized on both Mn3+ cation and O2- anion. The full (electronic and ionic) lattice relaxation energy for a hole localized at the O-site is estimated as 2.4 eV which is appreciably greater than that of 0.8 eV for a hole localized at the Mn-site, indicating on the strong electron-phonon interaction in the former case. Using a Born-Haber cycle we examine thermal and optical energies of the hole formation associated with electron ionization from Mn3+, O2- and La3+ ions in LaMnO3 lattice. For these calculations we derive a phenomenological value for the second electron affinity of oxygen in LaMnO3 lattice by matching the optical energies of La4+ and O- hole formation with maxima of binding energies in the experimental photoemission spectra. The calculated thermal energies predict that the electronic hole is marginally more stable in the Mn4+ state in LaMnO3 host lattice, but the energy of a hole in the O- state is only higher by a small amount, 0.75 eV, rather suggesting that both possibilities should be treated seriously. We examine the energies of a number of fundamental optical transitions, as well as those involving self-trapped holes of Mn4+ and O- in LaMnO3 lattice. The reasonable agreement with experiment of our predicted energies, linewidths and oscillator strengths leads us to plausible assignments of the optical bands observed. We deduce that the optical band near 5 eV is associated with O(2p) - Mn(3d) transition of charge-transfer character, whereas the band near 2.3 eV is rather associated with the presence of Mn4+ and/or O- self-trapped holes in non-stoichiometric LaMnO3 compound.

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