Graphene is an extremely intriguing material that is arousing a formidable amount of interest in many different disciplines. Surface science has not been immune to this fascination and has quickly made its contribution to the synthesis and study of the fundamental properties of systems like epitaxial graphene films, nanoribbons, nanopatches, providing a basic knowledge, which has been successfully capitalized upon by technologists and material scientists. %26lt;br%26gt;Nowadays, the focus of scientists%26apos; attention has moved towards more complex systems like chemically modified graphene and 3D systems based on the assembly of graphene sheets. However, despite many successful applications and the synthesis of very different materials, a basic understanding of the phenomena taking place at the atomic level is still missing, as is a clear correlation between structure and properties. Surface science, by virtue of its reductionist approach, can certainly make an important contribution to these new branches of research. Graphene is a perfect candidate for the realization of highly controlled model systems, in which to study the evolution from 2D to 3D topology or the new properties engendered by the substitution of carbon atoms with selected heteroatoms or entire functional groups. %26lt;br%26gt;Graphene has also proved to be an effective and versatile support: by acting on the nanostructure and defectivity of carbon sheets, it is possible to obtain highly controlled and easily tunable nanoparticles, opening the way to the rational design of new materials, and to the development of quite powerful model systems for heterogeneous catalysis investigations. Finally, graphene has proven to be extremely interesting as an advanced electrode for many electrochemical applications, and the study of the phenomena taking place at the solid-electrolyte interface is of paramount importance. This field could be the perfect context where the newly born discipline, electrochemical surface science, can advance and thrive, demonstrating all its potential.

• 出版日期2013-3