Ordered semiconducting nitrogen-graphene alloys

Abstract

The interaction between substitutional nitrogen atoms in graphene is studied by performing firstprinciples calculations. The effective nearest-neighbor interaction between nitrogen dopants is found to be highly repulsive because of the strong electrostatic repulsion between nitrogen atoms. This interaction prevents the full nitrogen-carbon phase separation in nitrogen-doped graphene. Interestingly, there are two relatively stable nitrogen-nitrogen pair configurations, whose stability can be attributed to the anisotropy in the charge redistribution induced by nitrogen doping. We reveal two stable, ordered, semiconducting N-doped graphene structures, C 3N and C 12N, through the cluster-expansion technique and particle-swarm optimization method. In particular, we show that C 12N has a direct band gap of 0.98 eV. The heterojunctions between C 12N and graphene nanoribbons might be a promising basis for organic solar cells.