English

Bounded particle interactions driven by a nonlocal dual Chern-Simons model

High Energy Physics - Theory 2019-10-03 v2 Strongly Correlated Electrons High Energy Physics - Phenomenology

Abstract

Quantum electrodynamics (QED) of electrons confined in a plane and that yet can undergo interactions mediated by an unconstrained photon has been described by the so-called {\it pseudo-QED} (PQED), the (2+1)-dimensional version of the equivalent dimensionally reduced original QED. In this work, we show that PQED with a nonlocal Chern-Simons term is dual to the Chern-Simons Higgs model at the quantum level. We apply the path-integral formalism in the dualization of the Chern-Simons Higgs model to first describe the interaction between quantum vortex particle excitations in the dual model. This interaction is explicitly shown to be in the form of a Bessel-like type of potential in the static limit. This result {\it per se} opens exciting possibilities for investigating topological states of matter generated by interactions, since the main difference between our new model and the PQED is the presence of a nonlocal Chern-Simons action. Indeed, the dual transformation yields an unexpected square root of the d'Alembertian operator, namely, ()1(\sqrt{-\Box})^{-1} multiplied by the well-known Chern-Simons action. Despite the nonlocality, the resulting model is still gauge invariant and preserves the unitarity, as we explicitly prove. {}Finally, when coupling the resulting model to Dirac fermions, we then show that pairs of bounded electrons are expected to appear, with a typical distance between the particles being inversely proportional to the topologically generated mass for the gauge field in the dual model.

Keywords

Cite

@article{arxiv.1901.00513,
  title  = {Bounded particle interactions driven by a nonlocal dual Chern-Simons model},
  author = {Van Sérgio Alves and E. C. Marino and Leandro O. Nascimento and J. F. Medeiros Neto and Rodrigo F. Ozela and Rudnei O. Ramos},
  journal= {arXiv preprint arXiv:1901.00513},
  year   = {2019}
}

Comments

7 pages. Replaced with version matching published one in the Phys. Lett. B

R2 v1 2026-06-23T07:01:45.408Z