Antipodal (trans-1) Diels-Alder bis-adducts 3 and 7 ± 9 of [5,6]fullerene-C 60 -I h (1) with some anthracenes were prepared highly regioselectively by heating mixtures of the solid 1 and anthracene or of (one of) three alkyl-substituted anthracenes in the absence of solvents (Scheme 2). Other bis-cycloadducts were not detected, but lesser amounts of mono-cycloadducts 2 and 4 ± 6, respectively, were also formed. Heating of solvent-free mixtures of 1 and three other alkyl-substituted anthracenes did not result in a detectable amount of (antipodal) bis-cycloadducts. The antipodal bis-adduct 7 of 1 and of 1-methylanthracene was analyzed by X-ray crystallography. The preparative outcome of heating of anthracenes and solid 1 parallels the result of the heating of the corresponding crystalline mono-adducts of anthracenes and 1. Both approaches reveal a remarkably consistent dependence of the reaction upon the presence and position of alkyl substituents at the anthracene unit. The regioselective assembly of antipodal bis-adducts from anthracene(s) and 1 cannot be rationalized by their (inherent molecular) stability, but it indicates the crucial control of the lattice. Introduction. ± Fullerenes, the spherical C-molecules [1 ± 3], are fascinating targets of chemistry, which also have enriched several other areas of the natural sciences [4 ± 6]. The original synthetic interests concerned the preparation of a variety of uniformly (mono)functionalized fullerenes [4] [6 ± 8]. More recently, the regio-and stereoselectivity of multifunctionalization reactions of the fullerenes has become a central focus, for the purpose of exploiting the spherical and polyunsaturated nature of the fullerenes [5] [6] [9 ± 12]. Several elegant synthetic strategies were developed, among these, Diederichs method of tether-directed remote functionalization [5] [9] and the reversible template-directed activation of fullerenes, used by Hirsch, Rubin, and others [6c] [10] [12c] [13].The high symmetry and pronounced dienophilic reactivity of the electrophilic [5,6]fullerene C 60 (1) rendered 1 an attractive target for a variety of [4 2]-cycloaddition reactions, which were found to occur at one of the 30 equivalent (6,6)-bonds of 1 exclusively [5] [6]. Cyclic dienes, anthracenes, and other polycyclic aromatics proved to represent useful addends in mono-and multiple cycloaddition processes with C 60 [8] [12] [14]. The mono-adduct 2 (9',10'-dihydro[9,10]ethanoanthra [11',12': 1,9][5,6]fullerene-C 60 -I h ) of anthracene and of C 60 can easily be prepared
