Application of Generalized Periodic Anderson Hamiltonians to the Superconducting Nickelates

Abstract

We study the extent to which a three-dimensional dispersing Periodic Anderson Model (PAM) can explain the emergence of novel superconductivity in the Infinite-Layer Nickelate compounds. By going beyond frequently used 2D models, the 3D dispersing PAM allows us to incorporate effects of finite out-of-plane hopping and orbital hybridization in describing these systems. Using an unbiased functional Renormalization Group (fRG) approach, we show that dx2-y2 superconductivity arises in a series of 3D ab-initio models of the Nickelates ( e.g.RNiO2), where R is a rare earth element. We the study the impact of going beyond the Ni-d orbital by including the R-dz2 and the interstitial-s as hybridizing conducting bands. We explore the dependence of the models on key parameters, including the local Hubbard coupling, doping and temperature. We find the hybridization with the interstitial-s band driving a 3D dz2-r2-type superconductivity while out of plane hopping primarily enhances an s-wave superconducting order.