Relationship between atomic and electronic structure in Ln-bearing oxides

BP Uberuaga and V Kocevski and AA Talapatra and BK Derby and ER Kennedy, PHYSICAL REVIEW MATERIALS, 9, 103603 (2025).

DOI: 10.1103/kttx-qmtd

Metastable states of matter are of great interest as they offer the promise of novel functionality. They are often a natural consequence of exposure to nonequilibrium environments. In oxides, metastability can take the form of new polymorphs, chemical disorder, and even amorphization. While significant attention has been given to the impact those changes have on the atomic properties of the material, the corresponding changes in the electronic structure have received less attention. Here, using density functional theory, we consider how the electronic structure varies with potential metastable structures in two classes of lanthanide-bearing oxides-pyrochlores and interlanthanide sesquioxides. We find that the changes depend strongly on both the crystal structure and crystal chemistry of the compound with, for example, disordering and amorphization either increasing or decreasing the bandgap depending on the chemistry. For the A2B2O7 pyrochlores, we find different dependencies of the bandgap on the A = Ln cations as the B cation is changed, which we relate to the nature of the density of states at the conduction band minimum for different B chemistries. Our calculations are validated by electron energy loss spectroscopy measurements for two pyrochlore compounds in which amorphization does reduce the bandgap, consistent with our calculations on these two compounds. Our results highlight the relationship between atomic and electronic structure and how radiation can be used to modify and potentially control the electronic properties of oxides.

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