First-principles study on the electronic and transport properties of periodically nitrogen-doped graphene and carbon nanotube superlattices

Abstract

Prompted by recent reports on 3 × 3 graphene superlattices with intrinsic inter-valley interactions, we perform first-principles calculations to investigate the electronic properties of periodically nitrogen-doped graphene and carbon nanotube nanostructures. In these structures, nitrogen atoms substitute one-sixth of the carbon atoms in the pristine hexagonal lattices with exact periodicity to form perfect 3 × 3 superlattices of graphene and carbon nanotubes. Multiple nanostructures of 3 × 3 graphene ribbons and carbon nanotubes are explored, and all configurations show nonmagnetic and metallic behaviors. The transport properties of 3 × 3 graphene and carbon nanotube superlattices are calculated utilizing the non-equilibrium Green's function formalism combined with density functional theory. The transmission spectrum through the pristine and 3 × 3 armchair carbon nanotube heterostructure shows quantized behavior under certain circumstances.