Formation of the icosahedral C 60 fullerene via migration of single sp atoms and annihilation of sp-atom pairs.

The disappearance of sp 2 structural defects during abundant fullerene isomer formation is considered within the framework of the atomistic mechanism with participation of carbon atoms with sp hybridization. The study is carried out using the example of the icosahedral C 60 - I h fullerene formation from the appropriate C 58 - C 2v fullerene with a 7-ring. In this case the studied atomistic mechanism includes the following stages: (1) insertion of single carbon atoms into the fullerene from carbon vapor as an sp-atom instead of or above a bond, (2) directional migration of the sp-atom positions towards the 7-ring with decrease of energy, and (3) meeting of two sp atoms near the 7-ring with annihilation of the sp-atom pair and formation of the sp 2 structure of the C 60 - I h fullerene. The probabilities of all possible sp-atom positions on the appropriate C 58 - C 2v fullerene shell are estimated as a function of temperature using the total energies of these positions obtained by spin-polarized density functional theory calculations using the PBE functional. Based on these estimations, it is shown that formation of the C 60 - I h isomer is the most probable within the framework of the considered mechanism relative to other C 60 isomers. The energetics of sp-atom pair annihilation in the formation of the C 60 - I h isomer is also studied via DFT calculations. The advantages of the considered atomistic mechanism of the abundant fullerene isomer formation are discussed.