Abstract

We discuss several aspects of a generalization of the Chern-Simons action containing the pseudo-differential operator$\sqrt{-\Box}$, which we shall call pseudo Chern-Simons (PCS). Firstly, we derive the PCS from the bosonization of free massive Dirac particles in (2+1)D in the limit when $m^2\ll p^2$, where $m$ is the fermion mass and $p$ is its momentum. In this regime, the whole bosonized action also has a modified Maxwell term, involving the same pseudo-differential operator. Furthermore, the large-mass $m^2\gg p^2$ regime is also considered. We also investigate the main effects of the PCS term into the Pseudo quantum electrodynamics (PQED), which describes the electromagnetic interactions between charged particles in (2+1)D. We show that the massless gauge field of PQED becomes massive in the presence of a PCS term, without the need of a Higgs mechanism. In the nonrelativistic limit, we show that the static potential has a repulsive term (given by the Coulomb potential) and an attractive part (given by a sum of special functions), whose competition generates bound states of particles with the same charge. Having in mind two-dimensional materials, we also conclude that the presence of a PCS term does not affect the renormalization either of the Fermi velocity and of the band gap in a Dirac-like material.

Highlights

  • After the experimental realization of graphene [1], quantum electrodynamics (QED) has been used as an efficient tool for describing the electronic properties in planar materials

  • We investigate the main effects of the PCS term into the pseudo-quantum electrodynamics (PQED), which describes the electromagnetic interactions between charged particles in ð2 þ 1ÞD

  • PQED [4] is a theory formulated in ð2 þ 1ÞD, which describes the electromagnetic interactions of charged particles constrained to move on a plane and it is a very useful tool for calculating either new topological states of matter [8] or renormalized parameters [9,10]

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Summary

INTRODUCTION

After the experimental realization of graphene [1], quantum electrodynamics (QED) has been used as an efficient tool for describing the electronic properties in planar materials. PQED [4] ( referred to as reduced quantum electrodynamics RQED [5,6,7]) is a theory formulated in ð2 þ 1ÞD, which describes the electromagnetic interactions of charged particles constrained to move on a plane and it is a very useful tool for calculating either new topological states of matter [8] or renormalized parameters [9,10] As we shall conclude later, this gauge field has a PCS term, providing a massive θ-parameter and mass generation This is similar to what happens in the Maxwell-Chern-Simons theory. In Appendix B, we calculated the screening effect on the static interaction potential using the RPA approach and adopting the 4 × 4 representation for the Dirac matrices

BOSONIZATION OF FREE MASSIVE DIRAC FERMIONS
Two-dimensional electrons
THE PSEUDO-CHERN-SIMONS MODEL
Feynman rules
SCREENING EFFECT ON THE GAUGE FIELD
THE ANISOTROPIC ELECTRON SELF-ENERGY
DISCUSSION

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