Doping of epitaxial graphene by direct incorporation of nickel adatoms

Direct incorporation of Ni adatoms during graphene growth on Ni( 111) is evidenced by scanning tunneling microscopy. The structure and energetics of the observed defects is thoroughly characterized at the atomic level on the basis of density functional theory calculations. Our results show the feasibility of a simple scalable method, which could be potentially used for the realization of macroscopic practical devices, to dope graphene with a transition metal. The method exploits the kinetics of the growth process for the incorporation of Ni adatoms in the graphene network.

Doping of epitaxial graphene by direct incorporation of nickel adatoms

Nanolithography of the nanocorral structure of chemisorbed oxygen atoms on the graphitic lattice

Mechanistic study on the evolution of vacancies in graphene by oxidation by scanning tunneling microscopy

In-situ atomic level observation of the strain response of graphene lattice

In-situ atomic level observation of the strain response of graphene lattice

Mechanistic study on the evolution of vacancies in graphene by oxidation by scanning tunneling microscopy

Nanolithography of the nanocorral structure of chemisorbed oxygen atoms on the graphitic lattice