Guidelines for band gap opening in graphene superlattices with periodic π-vacancy distribution

Abstract

Periodic π-vacancies in graphene superlattices (GSLs) provide a symmetry-based route to band-gap opening in graphene by modifying the π-band dispersion. However, the symmetry conditions that determine whether a vacancy motif can open a band gap remain unclear. Here, we investigate periodic π-vacancy GSLs using a nearest-neighbor tight-binding model with one pz orbital per carbon site to identify the symmetry requirements for gap opening. π-vacancies, representing functionalized, substituted, or missing carbon sites, are modeled as site deletions in the π basis, with all hopping matrix elements to and from the deleted sites set to zero. We focus on π-vacancy motifs with C2 and C3 point-group symmetry. A 3n × 3n GSL, where n=1,2,3,… is the integer scaling factor multiplying the honeycomb primitive-cell vectors, folds K and K' to and can therefore open a band gap. For C3-type vacancies, the Dirac cones remain pinned at high-symmetry points and thus stay at in folded 3n GSLs. In contrast, C2-type vacancies that reduce the global point group of the GSL to D2h by preserving a pair of perpendicular mirror symmetries, σv σd, can also constrain the Dirac cones to . When the σv and σd mirror planes are absent, the cones are allowed to shift away from to ( q, q) in the 3n superlattice.