Interorbital interaction in the one-dimensional periodic Anderson model: A density-matrix renormalization-group study

Abstract

We investigate the effect of the Coulomb interaction, Ucf, between the conduction and f electrons in the periodic Anderson model using the density-matrix renormalization-group algorithm. We calculate the excitation spectrum of the half-filled symmetric model with an emphasis on the spin and charge excitations. In the one-dimensional version of the model it is found that the spin gap is smaller than the charge gap below a certain value of Ucf and the reversed inequality is valid for stronger Ucf. This behavior is also verified by the behavior of the spin and density correlation functions. We also perform a quantum information analysis of the model and determine the entanglement map of the f and conduction electrons. It is revealed that for a certain Ucf the ground state is dominated by the configuration in which the conduction and f electrons are strongly entangled, and the ground state is almost a product state. For larger Ucf the sites are occupied alternatingly dominantly by two f electrons or by two conduction electrons.