A computational NICS and 13C NMR characterization of the polyfluorofullerenes C60Fn (n = 18, 20, 24, 36 and 48)

A density functional study has been performed to investigate electronic and magnetic properties of polyfluorofullerenes C60Fn (n = 18, 20, 24, 36, and 48) based on NMR parameters and NICS indices. A few picks appear in the 13C NMR pattern of each polyfluorofullerene which show the electrostatic environments of carbon nuclei are divided into a few layers related to three local structures around C atoms. Since, hexagons and pentagons in the zone of fluorinated carbon atoms are puckered, the range of isotropic chemical shifts (δiso) related to each group of C atoms are caused by different curvatures at the corresponding sites. According to the calculated spherical excesses Φi, chemical shifts are strongly sensitive to the curvature at the corresponding sites in the fullerene cage, so slightly difference in the Φi of carbon atoms leads to change in their δiso values. Moreover, the magnetic properties are examined inside the compounds indicating that independent of the type of polyfluorofullerenes NICS values are strongly negative at the middle of the cage except for the C60F24 and C60F48. The predicted NICS values may be also useful for identification of polyfluorofullerenes through their endohedral 3He NMR chemical shifts.

Graphical abstractA DFT study to investigate electronic and magnetic properties of polyfluorofullerenes C60Fn (n = 18, 20, 24, 36, and 48) based on NMR parameters and NICS indices.Figure optionsDownload full-size imageDownload as PowerPoint slideHighlights► Distinct picks are appeared in the 13C NMR patterns obtained for all polyfluorofullerenes. ► The picks are related to C atoms with different local structures. ► Based on the spherical excesses Φi, isotropic chemical shifts are sensitive to the curvature. ► Slightly differences in Φi for C atoms with given local structure lead to change in chemical shifts. ► Negative NICS values are obtained in the middle of all polyfluorofullerene cages.