Electrical resistivity of heavy-fermion systems with nonmagnetic impurities

We study nonmagnetic impurities, i.e., ''Kondo holes,'' in the periodic Anderson model in infinite dimensions d=infinity. We use standard perturbation theory up to second order in the Coulomb correlation U for the f electrons together with the coherent potential approximation to treat the Kondo holes. Choosing the parameters so that the Fermi energy of the pure system (without impurities) lies within the hybridization gap, our theory describes the influence of ''Kondo holes'' on the transport properties of Kondo insulators like Ce3Bi4Pt3. For other parameters (total number of electrons per site) the dependence of the resistivity on nonmagnetic impurities in metallic heavy-fermion systems (such as CeAl3, CeCu6) is accounted for. For both situations we calculate the density of states and the electrical resistivity as a function of temperature for different impurity concentrations. Qualitatively we obtain the correct behavior of the electrical resistivity as a function of temperature, Kondo hole concentration, and the filling of the f electrons and the band electrons.