English

Dyonic zero-energy modes

Strongly Correlated Electrons 2019-01-07 v2

Abstract

One-dimensional systems with topological order are intimately related to the appearance of zero-energy modes localized on their boundaries. The most common example is the Kitaev chain, which displays Majorana zero-energy modes and it is characterized by a two-fold ground state degeneracy related to the global Z2\mathbb{Z}_2 symmetry associated with fermionic parity. By extending the symmetry to the ZN\mathbb{Z}_N group, it is possible to engineer systems hosting topological parafermionic modes. In this work, we address one-dimensional systems with a generic discrete symmetry group GG. We define a ladder model of gauge fluxes that generalizes the Ising and Potts models and displays a symmetry broken phase. Through a non-Abelian Jordan-Wigner transformation, we map this flux ladder into a model of dyonic operators, defined by the group elements and irreducible representations of GG. We show that the so-obtained dyonic model has topological order, with zero-energy modes localized at its boundary. These dyonic zero-energy modes are in general weak topological modes, but strong dyonic zero modes appear when suitable position-dependent couplings are considered.

Keywords

Cite

@article{arxiv.1807.09286,
  title  = {Dyonic zero-energy modes},
  author = {Morten I. K. Munk and Asbjørn Rasmussen and Michele Burrello},
  journal= {arXiv preprint arXiv:1807.09286},
  year   = {2019}
}

Comments

Published version; 33 pages, 10 figures

R2 v1 2026-06-23T03:13:04.316Z