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KY carried out the calculation, and drafted the manuscript. HI participated in the discussion. NK supervised the study and KH advised on the work. All authors read and approved the final manuscript.”
“Background The theoretical
and experimental HAS1 study of properties of graphene has attracted the attention of many authors in the last few years since a method to isolate single graphene layers was developed (the authors Geim and Novoselov were awarded with the Nobel prize). These graphene sheets may be stable enough to be freely suspended [1], which allows us to use them in solid state experiments. Besides, the electronic properties of graphene are surprising: one finds new quasi-particles described by the Dirac equation at low energies that behave like massless particles. This opens the possibility to study quantum electrodynamics properties in solid-state devices and to carry out new developments, e. g., biosensors (see other studies [2–10]). The influence of defects and edges in graphene properties has been widely studied [11–13]. Other authors made similar studies to ours but considered different geometries: Zhang et al. [14, 15] worked on transport with narrow ballistic ribbon of graphene with zigzag edges including topological defects. Carpio et al. [12] studied the electronic properties in a similar geometry but with dislocations consisting of heptagon-pentagon pairs in an hexagon lattice.