Band Structure and Spatial Localization of Electrons in Twisted Bilayer Graphene Nanoribbons

We have studied the band structure, density of states and spatial localization ofelectron in twisted bilayer nanoribbons by means of tight binding calculation. InChiral geometries, edge states are also related to the presence of zig-zag edge atoms,although they presented remarkable size effects. Physical properties of chiralgraphene nanoribbons and general edges can have a stong dependence on chirality.We have analysed the properties of edge states in twisted bilayaer ribbons,explaining their energy dispersion and spatial localization. The different splittingswere found in edge bands due to the inhomogeneous interplay coupling. For stackedzig-zag atoms the coupling was larger than corresponding edge states splitted apart,but edge states stemming from regions with stacking, where the interlayer couplingwas smaller and gave rise to zero energy bands. We have also been found that in theedge regions where top and bottom zig-zag terminations were stacked, inter-ribbontunneling between the dispersions less zero energy states created bonding andantibonding combination with energies away from the energy of the Dirac point. Theobtained results were found in good agreement with previously obtained results.