Low energy valence photoemission in the Anderson impurity model for Ce compounds

Abstract

The valence level photoemission spectra in the Anderson impurity model for Ce compounds at zero temperature are studied as a function of the photon energy ω. Most of former studies on Ce compounds are based on the sudden approximation, which is valid in high energy region. For the photoemission in the adiabatic limit of low energy region, one should consider the dipole matrix elements and the hole-induced photoelectron scattering potential. We can manage it by combining the time-evolution formalism and the 1/Nf scheme in a large f-level degeneracy Nf. This gives the exact results as Nf∞. In view of experiments on the valence photoemission, two contributions of 4f- and band emissions are mixed. We study the separate 4f and band contributions (from Ce 5d) and total emission including the interference between two on an equal footing with varying the photon energy. In the 4f-emission case, we also explore the effects of hole-induced scattering potential of the photoelectron with respect to ω. Its effects are found very similar to the core level photoemission in shake down case with a localized charge transfer excitation. Additionally, we examine the adiabatic-sudden transition in valence level photoemission for the present localized system through the simplified two-level model.

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