English

Electronic structure of cerium: A comprehensive first-principles study

Strongly Correlated Electrons 2019-01-16 v1 Materials Science

Abstract

Cerium, in which the 4ff valence electrons live at the brink between localized and itinerant characters, exhibits varying crystal structures and therefore anomalous physical properties with respect to temperature and pressure. Understanding its electronic structure and related lattice properties is one of the central topics in condensed matter theory. In the present work, we employed the state-of-the-art first-principles many-body approach (i.e., the density functional theory in combination with the single-site dynamical mean-field theory) to study its electronic structure thoroughly. The momentum-resolved spectral functions, total and 4f4f partial density of states, optical conductivities, self-energy functions, and atomic eigenstate histograms for cerium's four allotropes under ambient pressure were calculated and analyzed carefully. The calculated results demonstrate that the 4ff electrons in the α\alpha, β\beta, γ\gamma, and δ\delta phases are all correlated with heavily remormalized electron masses. In the α\alpha phase, the 4ff electrons tend to be itinerant, which cause strong hybridization between the 4ff and spdspd bands and remarkable 4ff valence state fluctuation. While for the other phases, the 4ff electrons are close to be localized. Our calculated results support the Kondo volume collapse scenario for the cerium αγ\alpha-\gamma transition. Finally, we examined the site dependence of 4f4f electronic structure in the β\beta phase. The calculated results suggest that it doesn't exhibit a site selective 4ff localized state, contrary to previous prediction.

Keywords

Cite

@article{arxiv.1807.06769,
  title  = {Electronic structure of cerium: A comprehensive first-principles study},
  author = {Li Huang and Haiyan Lu},
  journal= {arXiv preprint arXiv:1807.06769},
  year   = {2019}
}

Comments

14 pages, 9 figures

R2 v1 2026-06-23T03:05:20.084Z