Superfluid transition of bond bipolarons with long-range Coulomb repulsion in two dimensions
Abstract
Using numerically exact diagrammatic Monte Carlo simulations in the two-electron (single-bipolaron) sector, we explore the impact of long-range Coulomb repulsion on the dilute-limit Berezinskii--Kosterlitz--Thouless (BKT) transition temperature Tc of bipolarons on a two-dimensional square lattice. We study the bond Su--Schrieffer--Heeger model, in which bond phonons modulate the electron hopping. In the absence of long-range repulsion, this model was shown to support small, light bipolarons with a comparatively high transition temperature PhysRevX.13.011010. Here we find that long-range Coulomb repulsion suppresses the optimal Tc but leaves it appreciable over a broad parameter window, including the adiabatic regime ω/t=0.5 at a representative Coulomb strength V=U/10 (with U the on-site repulsion). Our results provide controlled single-bipolaron inputs for dilute-limit Tc estimates in the presence of long-range repulsion.
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