Construction of a Microscopic Model for Yb and Tm Compounds on the Basis of a j-j Coupling Scheme

Abstract

We provide a prescription to construct a microscopic model for heavy lanthanide systems such as Yb and Tm compounds by exploiting a j-j coupling scheme. Here we consider a situation with a large spin-orbit coupling, in which j=5/2 sextet is fully occupied, while j=7/2 octet is partially occupied, where j denotes total angular momentum. We evaluate crystalline electric field potentials and Coulomb interactions among the states of the j=7/2 octet to construct a local Hamiltonian in the j-j coupling scheme. Then, it is found that the local f-electron states composed of the j=7/2 octet agree quite well with those of seven f orbitals even for a realistic value of the spin-orbit coupling. As an example of the application of the present model, we discuss low-temperature multipole states of Yb- and Tm-based filled skutterudites by analyzing multipole susceptibility of the Anderson model in the j-j coupling scheme with the use of a numerical renormalization group technique. From the comparison with the numerical results of the seven-orbital Anderson model, it is concluded that the multipole state is also well reproduced by the j-j coupling model, even when we include the hybridization between conduction and f electrons for the realistic value of the spin-orbit coupling. Finally, we briefly discuss future applications of the present prescription for theoretical research on heavy lanthanide compounds.