AI Article Synopsis
- The study investigates the effects of strong correlations in rare-earth pnictides, focusing on localized 4f states and their impact on valence electron states.
- Using erbium arsenide as a case study, the researchers apply dynamical mean-field theory to analyze the 4f shell's atomic multiplet structure and its interaction with electronic Fermi surfaces.
- The findings help clarify the long-standing issue of magnetization saturation in magnetic fields and provide quantitative alignment with experimental data on Shubnikov-de Haas frequencies related to Fermi surfaces.
Article Abstract
We present a study of the effects of strong correlations in rare-earth pnictides, in which localized 4f states simultaneously retain atomiclike character and strongly influence the free-electron-like valence electron states. Using erbium arsenide as our example, we use a modern implementation of dynamical mean-field theory to obtain the atomic multiplet structure of the Er3+ 4f shell, as well as its unusually strong coupling to the electronic Fermi surfaces; these types of behavior are not correctly described within conventional electronic-structure methods. We are then able to explain the long-standing theoretical question of the quasisaturation of magnetization in an applied magnetic field, and to obtain the first quantitative agreement with experimental Shubnikov-de Haas frequencies of the Fermi-surface sheets.
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| http://dx.doi.org/10.1103/PhysRevLett.102.096401 | DOI Listing |
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