Metal-doped carbon nanotubes interacting with vitamin C.

In this paper, the structural, electronic and magnetic properties of carbon nanotubes doped with Al, Fe, Mn and Ti atoms interacting with vitamin C molecules are studied through first principles simulations based on the density functional theory. The charge transfers are obtained from the vitamins into the tubes for adsorption and substitutional doping cases. The highest binding energies of vitamin C molecules are calculated for the Al substitutional and Ti adsorbed cases, with values of about 1.

Carbon nanostructures interacting with vitamins A, B3 and C: ab initio simulations.

The energetic and structural properties of fullerenes, carbon nanotubes and graphene interacting with vitamins A, B3 and C were studied by first principles simulations. These vitamins, which have antioxidant activities, give support to the cellular metabolism, have biochemical, therapeutic and cosmetic functions, and when combined with carbon nanostructures may have their chemical instability controlled. In this work, the results illustrate that the strongest interaction is between vitamin A and graphene.