In our most recent publication we studied the exohedrally metal decorated carbon-fullerenes. These systems are a promising material for its good hydrogen adsorption (high concentrations and with optimal binding energies) properties. Since their geometry and type of coverage play a key role in determining the H2 adsorption mechanism, in this paper just accepted in Carbon Journal, we studied in a fully ab-initio, unbiased structure fashion the configurational space of decorated C60 fullerenes.
Many of the hitherto postulated ground state structures are not ground states. We could determine the energetically lowest configurations for decorations with a varying number of decorating atoms for alkali metals, alkaline-earth metals as well as some other important elements and find that the dense uniform distribution of the decorating atoms over the surface of the C60, desired for hydrogen storage, can be obtained only for a few elements. An understanding of the behavior of the decorating atoms can be obtained
by analyzing their bonding characteristics.