Charge Order in the half-filled bond-Holstein Model

Abstract

We use determinant quantum Monte Carlo to study the half-filled `bond-Holstein' model on a square lattice. We find that the model exhibits a charge-density-wave (CDW) phase transition with a critical temperature Tcdw considerably higher than that of the canonical `site-Holstein' model. Using a finite-size scaling analysis of the charge structure factor S cdw, we obtain Tcdw to greater than one percent accuracy. At the same time, local observables also show clear signatures consistent with the transition temperatures inferred from our scaling analysis. We attribute the enhanced CDW tendencies to a phonon-mediated nearest-neighbor electron repulsion that is directly proportional to the dimensionless electron-phonon coupling λ in the atomic (t→ 0) limit. This behavior contrasts with the site-Holstein case, where the same limit yields only an on-site attraction. We supplement our analysis with results from several unsupervised machine learning methods, which not only confirm our estimates of Tcdw but also provide insight into the high-temperature crossover between a metallic and bipolaron liquid regime.