Mott metal-insulator transition in a modified periodic Anderson model: Insights from entanglement entropy and role of short-range spatial correlations (2506.16533v1)

Abstract: The Mott-Hubbard metal-insulator transition is a paradigmatic phenomenon where Coulomb interactions between electrons drive a metal-insulator phase transition. It has been extensively studied within the Hubbard model, where a quantum critical transition occurs at a finite temperature second-order critical point. This work investigates the Mott metal-insulator transition in a modified periodic Anderson model that may be viewed as a three-orbital lattice model including an interacting, localized orbital coupled to a delocalized conduction orbital via a second conduction orbital. This model could also be viewed as a bilayer model involving a conventional periodic Anderson model layer coupled to a metallic layer. Within the dynamical mean field theory, this model possesses a strictly zero temperature quantum critical point separating a Fermi liquid and a Mott insulating phase. By employing a simplified version of the dynamical mean field theory, namely, the two-site or linearized dynamical mean field theory, we provide an analytical estimate of the critical parameter strengths at which the transition occurs at zero temperature. We also provide an analytical estimate of the single-site von Neumann entanglement entropy. This measure can be used as a robust identifier for the phase transition. We extend these calculations to their cluster version to incorporate short-range, non-local spatial correlations and discuss their effects on the transition observed in this model.