High Resolution Photoemission Study on Low-TK Ce Systems: Kondo Resonance, Crystal Field Structures, and their Temperature Dependence
Abstract
We present a high-resolution photoemission study on the strongly correlated Ce-compounds CeCu6, CeCu2Si2, CeRu2Si2, CeNi2Ge2, and CeSi2. Using a normalization procedure based on a division by the Fermi-Dirac distribution we get access to the spectral density of states up to an energy of 5 kBT above the Fermi energy EF. Thus we can resolve the Kondo resonance and the crystal field (CF) fine-structure for different temperatures above and around the Kondo temperature TK. The CF peaks are identified with multiple Kondo resonances within the multiorbital Anderson impurity model. Our theoretical 4f spectra, calculated from an extended non-crossing approximation (NCA), describe consistently the observed photoemission features and their temperature dependence. By fitting the NCA spectra to the experimental data and extrapolating the former to low temperatures, TK can be extracted quantitatively. The resulting values for TK and the crystal field energies are in excellent agreement with the results from bulk sensitive measurements, e.g. inelastic neutron scattering.
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