Structure, Stability, and Cluster-Cage Interactions in Nitride Clusterfullerenes M₃N@C_2n (M = Sc, Y; 2n = 68−98):  a Density Functional Theory Study

Abstract: Extensive semiempirical calculations of the hexaanions of IPR (isolated pentagon rule) and non-IPR isomers of C(68)-C(88) and IPR isomers of C(90)-C(98) followed by DFT calculations of the lowest energy structures were performed to find the carbon cages that can provide the most stable isomers of M(3)N@C(2n) clusterfullerenes (M = Sc, Y) with Y as a model for rare earth ions. DFT calculations of isomers of M(3)N@C(2n) (M = Sc, Y; 2n = 68-98) based on the most stable C(2n)(6-) cages were also performed. The low… Show more

“…Therefore, we conclude that the cluster is able to rotate inside the I h -C 80 cage, in good agreement with experiments [38] and with previous theoretical results. [64,71] The most stable orientational isomer is very similar to that found by Popov and Dunsch (rotation of 21.58 with respect to the isomer with C 3v symmetry). [69] For the neutral Sc 3 N@D 5h -C 80 , free rotation of the cluster was also predicted, in good agreement with experiment, [72] since several orientational isomers show relative energies smaller than 4 kcal mol…”

“…[63] In recent work, Popov and Dunsch have also proposed cage isomers for large MNEFs (from C 90 to C 98 ) based on the stability of the empty fullerenes in their hexa-A C H T U N G T R E N N U N G anionic state C 2n 6À . [64] In most cases the cage structures predicted by Popov and Dunsch and by our group match fairly well.…”

Electronic Structure and Redox Properties of Metal Nitride Endohedral Fullerenes M₃N@C_2n (M=Sc, Y, La, and Gd; 2n=80, 84, 88, 92, 96)

“…Therefore, we conclude that the cluster is able to rotate inside the I h -C 80 cage, in good agreement with experiments [38] and with previous theoretical results. [64,71] The most stable orientational isomer is very similar to that found by Popov and Dunsch (rotation of 21.58 with respect to the isomer with C 3v symmetry). [69] For the neutral Sc 3 N@D 5h -C 80 , free rotation of the cluster was also predicted, in good agreement with experiment, [72] since several orientational isomers show relative energies smaller than 4 kcal mol…”

“…[63] In recent work, Popov and Dunsch have also proposed cage isomers for large MNEFs (from C 90 to C 98 ) based on the stability of the empty fullerenes in their hexa-A C H T U N G T R E N N U N G anionic state C 2n 6À . [64] In most cases the cage structures predicted by Popov and Dunsch and by our group match fairly well.…”

Electronic Structure and Redox Properties of Metal Nitride Endohedral Fullerenes M₃N@C_2n (M=Sc, Y, La, and Gd; 2n=80, 84, 88, 92, 96)

“…4a and 49 , to discern which Ca@C 2n cages exhibit enhanced stability. We find that the relative energies of empty cage dianions and Ca@C 2n follow the same trends and, therefore, the ionic model is applicable to Ca-encapsulated EMFs.…”

Bottom-up formation of endohedral mono-metallofullerenes is directed by charge transfer

“…Based on the electronic structure of the free fullerene cage, Poblet et al [14] proposed isomer 86 of C 92 (see Figure 3) with symmetry T as the most suitable isomer to encapsulate a MN cluster. Nevertheless, Popov and Dunsch found isomer 85 (Y 3 N@C 92 ) with D 3 symmetry more stable than isomer 86 by about 14 kcal mol À1 when the internal cluster is Y 3 N [15] . If the metal is lanthanum, the difference in the stability between the two isomers is 7.7 kcal mol À1 , isomer 85 again being the most stable species.…”

“…In most of the cases, the cage structures predicted by both groups coincide. [15] Herein we report the synthesis, electrochemistry, and theoretical characterization of the large MNEFs M 3 N@C 2n family (M = La, Ce, and Pr; n = 46 and 48). The combined electrochemical and computational analyses of the series from M 3 N@C 80 to M 3 N@C 96 verify the ionic model M 3 N 6+ @ C 2n 6À for MNEFs.…”

Trimetallic Nitride Endohedral Fullerenes: Experimental and Theoretical Evidence for the M₃N⁶⁺@C_2n⁶⁻ model