The Kondo effect in ferromagnetic quantum critical CeRh6Ge4

Abstract

The mechanism of a pressure-induced quantum critical point in the heavy fermion ferromagnet CeRh6Ge4 has attracted interest, as ferromagnetic quantum criticality in a clean itinerant Ce compound is typically avoided. The localized versus itinerant character of the 4f electrons is a key aspect for understanding this behavior. We investigated the electronic structure of the 4f shell in CeRh6Ge4 using core-level photoelectron and x-ray absorption spectroscopy, demonstrating the hybridization of Ce 4f with the conduction electrons. Linearly polarized x-ray absorption reveals a temperature-dependent linear dichroism consistent with the crystal-electric-field (CEF) sequence as inferred from the static susceptibility. This dichroism cannot be described by an ionic full-multiplet model alone, but is reproduced by including the Kondo effect within a single-impurity Anderson model in the non crossing approximation (SIAM/NCA). The Kondo effect mixes higher lying crystal-field states into a resulting multiorbital ground state with 4f occupancy nf\,\,0.9. Deviations at low temperatures between the measured linear dichroism and calculated dichroism suggest an orbital-dependent Kondo effect. A scenario in which there is a multiorbital ground state and orbital-dependent Kondo hybridization should be a starting point for a model of pressure-induced criticality in CeRh6Ge4.