Correlation Effects on Coupled Electronic and Structural Properties of Doped Rare-Earth Trihydrides
Abstract
Rare-earth trihydrides (RH3) exhibit intriguing coupled electronic and structural properties as a function of doping, hydrogen vacancies, and thermodynamic conditions. Theoretical studies of these materials typically rely on density functional theory (DFT), including the use of small supercells that may underestimate strong correlation effects and structural distortions which in turn may influence their metallicity. Here, we elucidate the roles of lattice distortions and correlation effects on the electronic properties of pristine and doped RH3 by adopting DFT+U and Quantum Monte Carlo (QMC) methods. Linear-response constrained DFT (LR-cDFT) methods find Hubbard U ≈ 2 eV for Rd orbitals and U≈ 6 eV for Hs/Np orbitals. The small U on Lud orbitals is consistent with QMC calculations on LuH3 and LuH2.875N0.125. In pure face-centered-cubic (FCC) RH3 (R=Lu,Y), neither DFT nor DFT+U with the self-consistently determined U is enough to create a band gap, however a supercell with hydrogen distortions creates a small gap whose magnitude increases when performing DFT+U with self-consistently determined U values. Correlation effects, in turn, have a moderate influence on the coupled structural and electronic properties of doped RH3 compounds and may be important when considering the competition between structural distortions and superconductivity.
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