MAGIC NUMBERS AND STABLE STRUCTURES FOR FULLERENES, FULLERIDES AND FULLERENIUM IONS

MACROSCOPIC amounts of the two fullerenes C60 and C70 have been available for a year1, and have already had an enormous impact on research in chemistry and physics. Experimentalists are now turning their attention to the higher fullerenes2,3. Qualitative molecular-orbital theory predicts4-6 stability for Cn with n = 60, 70, (72), 76, 78, 84, . . . , of which all but C72 have now been produced by evaporation of graphite1-3, and in general for infinite series of closed-shell neutral fullerenes for n=60 + 6k (k≠1), 70+30k, 84+36k (all )7-9. Recent experimental observations of endohedral LaCn metallofullerenes10 have been rationalized in terms of 'magic numbers' for fullende anions Cn 2-, for which special stability is predicted11 at n=74, 82, 88, . . . ; but the exact extent of charge transfer in these complexes has yet to be determined. Here we present calculations of magic numbers in the fullerenium sequence Cn 2+ (n = 74, 80, (88), 92) and show that the electron count determines stability and the atom count determines structure in all three (neutral, anionic and cationic) series. Stable cations have two carbons more, and stable anions two carbons less, than the corresponding stable neutral cluster. We predict likely structures of the 'magic' cations.