Localization transition in one dimension using Wegner flow equations

Abstract

The flow equation method was proposed by Wegner as a technique for studying interacting systems in one dimension. Here, we apply this method to a disordered one dimensional model with power-law decaying hoppings. This model presents a transition as function of the decaying exponent α. We derive the flow equations, and the evolution of single-particle operators. The flow equation reveals the delocalized nature of the states for α<1/2. Additionally, in the regime, α>1/2, we present a strong-bond renormalization group structure based on iterating the three-site clusters, where we solve the flow equations perturbatively. This renormalization group approach allows us to probe the critical point (α=1). This method correctly reproduces the critical level-spacing statistics, and the fractal dimensionality of the eigenfunctions.