Exotic 4f Correlated Electronic States of Ferromagnetic Kondo Lattice Compounds ReRh6Ge4 (Re=Ce, Ho, Er, Tm)

Abstract

CeRh6Ge4 stands out as the first stoichiometric metallic compound with a ferromagnetic quantum critical point, thereby garnering significant attention. Ferromagnetic Kondo lattice compounds ReRh6Ge4 (Re=Ce, Ho, Er, Tm) have been systematically investigated with density functional theory incorporating Coulomb interaction U and spin-orbital coupling. We determined the magnetic easy axis of CeRh6Ge4 is within the ab plane, which is in agreement with previous magnetization measurements conducted under external magnetic field and muSR experiments. We also predicted the magnetic easy axes for the other three compounds. For TmRh6Ge4, the magnetic easy axis aligns along the c axis, thus preserving the C3 rotational symmetry of the c axis. Especially, there are triply degenerate nodal points along the -A direction in the band structure including spin-orbital coupling. A possible localized to itinerant crossover is revealed as 4f electrons increase from CeRh6Ge4 to TmRh6Ge4. Specifically, the 4f electrons of TmRh6Ge4 contribute to the formation of a large Fermi surface, indicating their participation in the conduction process. Conversely, the 4f electrons in HoRh6Ge4, ErRh6Ge4 and CeRh6Ge4 remain localized, which result in smaller Fermi surfaces for these compounds. These theoretical investigations on electronic structure and magnetic properties shed deep insight into the unique nature of 4f electrons, providing critical predictions for subsequent experimental studies.