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Localizing Transitions via Interaction-Induced Flat Bands

Strongly Correlated Electrons 2024-10-18 v1 Mesoscale and Nanoscale Physics High Energy Physics - Theory Mathematical Physics math.MP Quantum Physics

Abstract

This paper presents a theory of interaction-induced band-flattening in strongly correlated electron systems. We begin by illustrating an inherent connection between flat bands and index theorems, and presenting a generic prescription for constructing flat bands by periodically repeating local Hamiltonians with topological zero modes. Specifically, we demonstrate that a Dirac particle in an external, spatially periodic magnetic field can be cast in this form. We derive a condition on the field to produce perfectly flat bands and provide an exact analytical solution for the flat band wave functions. Furthermore, we explore an interacting model of Dirac fermions in a spatially inhomogeneous field. We show that certain Hubbard-Stratonovich configurations exist that ``rectify'' the field configuration, inducing band flattening. We present an explicit model where this localization scenario is energetically favorable -- specifically in Dirac systems with nearly flat bands, where the energy cost of rectifying textures is quadratic in the order parameter, whereas the energy gain from flattening is linear. In conclusion, we discuss alternative symmetry-breaking channels, especially superconductivity, and propose that these interaction-induced band-flattening scenarios represent a generic non-perturbative mechanism for spontaneous symmetry breaking, pertinent to many strongly-correlated electron systems.

Keywords

Cite

@article{arxiv.2308.16440,
  title  = {Localizing Transitions via Interaction-Induced Flat Bands},
  author = {Alireza Parhizkar and Victor Galitski},
  journal= {arXiv preprint arXiv:2308.16440},
  year   = {2024}
}

Comments

4.5 pages + supplemental material

R2 v1 2026-06-28T12:08:58.481Z