Rich essential properties of Si-doped graphene

A theoretical framework, which is under the first-principles calculations, is developed to fully explore the dramatic changes of essential properties due to the silicon-atom chemical modifications on monolayer graphenes. For the Si-chemisorption and Si-substituted graphenes, the guest-atom-diversified geometric structures, the Si- and C-dominated energy bands, the magnetic moments, the charge transfers, the spatial charge densities, the spin distribution configurations, and the van Hove singularities in the atom- and orbital-projected density of states are investigated thoroughly by the delicate evaluations and analyses. Such fundamental properties are sufficient in determining the critical physical and chemical pictures, in which the accurate multi-orbital hybridizations are very useful in comprehending the diverse phenomena, e.g., the C- and Si-co-dominated energy bands, the semiconducting or metallic behaviors, and the existence/absence of Dirac-cone band structures. This developing model could be generalized to other emergent layered materials.