Combining semi-local exchange with dynamical mean-field theory: electronic structure and optical response of rare-earth sesquioxides

Abstract

In rare-earth semiconductors, wide ligand p and rare-earth 5d bands coexist with localized, partially filled 4f shells. A simultaneous description for both extended and localized states represents a significant challenge for first-principles theories. Here, we combine an ab initio dynamical mean-field theory approach to strong local correlations with a perturbative application of the semi-local modified Becke-Johnson exchange potential to correct the semiconducting gap. We apply this method to calculate the electronic structure and optical response of the light rare-earth sesquioxides RE2O3 (RE= La, Ce, Pr and Nd). Our calculations correctly capture a non-trivial evolution of the optical gap in RE2O3 due to a progressive lowering of the 4f states along the series and their multiplet structure. 2p - 4f hybridization is found to induce a substantial upward shift for the occupied 4f states occurring within the p-d gap, thus reducing the magnitude of the optical gap. We show that a characteristic plateau observed in the optical conductivity in the Pr and Nd sequioxides right above their absorption edge is a fingerprint of 4f states located within the p-d gap.

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