A contractor-renormalization study of Hubbard plaquette clusters

TL;DR

This study uses the contractor-renormalization method to analyze the checkerboard Hubbard model, revealing that moderate inhomogeneity enhances hole pairing due to resonating valence bond correlations, with optimal pairing at specific inter-plaquette hopping values.

Contribution

It applies the contractor-renormalization technique to finite clusters of the Hubbard model, demonstrating how inhomogeneity influences pairing and magnetic properties.

Findings

Pair-binding energy and spin gap peak at intermediate t' and U.

Moderate inhomogeneity enhances hole pairing.

Pairing driven by kinetic energy and resonating valence bonds.

Abstract

We implement the contractor-renormalization method to study the checkerboard Hubbard model on various finite-size clusters as function of the inter-plaquette hopping t' and the on-site repulsion U at low hole doping. We find that the pair-binding energy and the spin gap exhibit a pronounced maximum at intermediate values of t' and U, thus indicating that moderate inhomogeneity of the type considered here substantially enhances the formation of hole pairs. The rise of the pair-binding energy for t'<t'_max is kinetic-energy driven and reflects the strong resonating valence bond correlations in the ground state that facilitate the motion of bound pairs as compared to single holes. Conversely, as t' is increased beyond t'_max antiferromagnetic magnons proliferate and reduce the potential energy of unpaired holes and with it the pairing strength. For the periodic clusters that we study the estimated phase ordering temperature at t'=t'_max is a factor of 2-7 smaller than the pairing temperature.