Bound States of Conical Singularities in Graphene-Based Topological Insulators

Abstract

We investigate the electronic structure induced by wedge-disclinations (conical singularities) in a honeycomb lattice model realizing Chern numbers γ= 1. We establish a correspondence between the bound state of (i) an isolated 0/2-flux, (ii) an isolated pentagon (n=1) or heptagon (n=-1) defect with an external flux of magnitude nγ 0/4 through the center and (iii) an isolated square or octagon defect without external flux, where 0=h/e is the flux quantum. Due to the above correspondence, the existence of isolated electronic states bound to the disclinations is robust against various perturbations. These results are also generalized to graphene-based time-reversal invariant topological insulators.