Endohedral chemical shifts in higher fullerenes with 72-86 carbon atoms

Abstract: For all isolated pentagon isomers of the fullerenes C 60 ±C 86 with nonzero HOMO±LUMO gap and for one nonclassical C 72 isomer (C 2v ), endohedral chemical shifts have been computed at the GIAO-SCF/ 3-21G level using B3LYP/6-31G* optimized structures. The experimental 3 He NMR signals are reproduced reasonably well in cases where assignments are unambiguous (e.g. C 60 , C 70 and C 76 ). On the basis of the calculated thermodynamic stability order and the comparison between the computed and experimental 3 He ch… Show more

“…The low-energy isomer C 80 : 2 has been synthesized and characterized by the 13 C NMR technique 5 and its structural assignment was confirmed by simulation of the 13 C NMR fingerprint 5 and endohedral 3 He chemical shift. 6 As Sc 3 N has at most D 3h symmetry, the two-signal highsymmetry 13 C NMR pattern must be the time average of a dynamically changing lower symmetry structure due to the long time-scale of NMR measurements 1 . Later, Sc 3 N@C 80 was reported by other groups.…”

13C NMR fingerprint characterizes long time-scale structure of Sc3N@C80 endohedral fullerene

“…The low-energy isomer C 80 : 2 has been synthesized and characterized by the 13 C NMR technique 5 and its structural assignment was confirmed by simulation of the 13 C NMR fingerprint 5 and endohedral 3 He chemical shift. 6 As Sc 3 N has at most D 3h symmetry, the two-signal highsymmetry 13 C NMR pattern must be the time average of a dynamically changing lower symmetry structure due to the long time-scale of NMR measurements 1 . Later, Sc 3 N@C 80 was reported by other groups.…”

13C NMR fingerprint characterizes long time-scale structure of Sc3N@C80 endohedral fullerene

“…The 2(N1) 2 rule has been investigated in detail for several fullerenes and heterofullerenes in terms of magnetic properties of these systems, [14,15,16] and the spherical aromaticity concept applied to fullerenes has recently been reviewed in reference [17]. It has also been suggested to extend the spherical electron-counting concept to s-bonded systems like clusters of hydrogen atoms.…”

From Rare Gas Atoms to Fullerenes: Spherical Aromaticity Studied From the Point of View of Atomic Structure Theory

“…Many of these studies have focused on the understanding of the main factors that govern the stability of fullerenes. [3,4] The stability of fullerenes has been extensively studied from the experimental point of view; [5] in particular, fragmentation experiments have proved the existence of the so-called magic-number fullerenes, [6] that is, fullerenes with a certain size that present a greater stability than their closer neighbours, for instance C 50 , C 60 and C 70 .…”

“…[7] This second rule is know as the pentagon adjacency penalty rule, PAPR. [8] Fullerenes with fused pentagonal rings, such as C 50 Cl 10 and the chlorine derivatives of C 56 and C 54 , have been isolated very recently. [9,10] As indicated above, all these fullerenes necessarily present adjacent pentagons in their structure.…”

“…These shells are completely filled when the number of p electrons is equal to 2(l + 1) 2 and, in these cases, the fullerenes present spherical aromaticity. [49,50] The concept of spherical aromaticity and its consequences for the reactivity of fullerenes was reviewed recently. [48,51] In the case of C 52 2 + , the number of p electrons (50) corresponds to a situation in which the g shell (l = 4) is filled.…”

Structure and Electronic Properties of Fullerenes C₅₂^q+: Is C₅₂²⁺ an Exception to the Pentagon Adjacency Penalty Rule?