A Nano-sized Supramolecule Beyond the Fullerene Topology

The reaction of [CpBnFe(η5-P5)] (1) (CpBn=η5-C5(CH2Ph)5) with CuI selectively yields a novel spherical supramolecule (CH2Cl2)3.4@[(CpBnFeP5)12{CuI}54(MeCN)1.46] (2) showing a linkage of the scaffold atoms which is beyond the Fullerene topology. Its extended CuI framework reveals an outer diameter of 3.7 nm—a size that has not been reached before using five-fold symmetric building blocks. Furthermore, 2 shows a remarkable solubility in CH2Cl2, and NMR spectroscopy reveals that the scaffold of the supramolecule remains intact in solution. In addition, a novel 2D polymer [{CpBnFe(η5-P5)}2{Cu6(μ-I)2(μ3-I)4}]n (3) with an uncommon structural motif was isolated. Its formation can be avoided by using a large excess of CuI in the reaction with 1.


In memory of Reinhard Schmutzler
Abstract: The reaction of [Cp Bn Fe(h 5 -P 5 )] (1) (Cp Bn = h 5 -C 5 (CH 2 Ph) 5 ) with CuI selectively yields a novel spherical supramolecule (CH 2 Cl 2 ) 3.4 @[(Cp Bn FeP 5 ) 12 {CuI} 54 (MeCN) 1.46 ] (2) showing a linkage of the scaffold atoms which is beyond the Fullerene topology. Its extended CuI framework reveals an outer diameter of 3.7 nm-a size that has not been reached before using five-fold symmetric building blocks. Furthermore, 2 shows a remarkable solubility in CH 2 Cl 2 , and NMR spectroscopy reveals that the scaffold of the supramolecule remains intact in solution. In addition, a novel 2D polymer [{Cp Bn Fe(h 5 -P 5 )} 2 {Cu 6 (m-I) 2 (m 3 -I) 4 }] n (3) with an uncommon structural motif was isolated. Its formation can be avoided by using a large excess of CuI in the reaction with 1.
The chemistry of supramolecular aggregates is one of the most interesting and fascinating fields in current research. [1] Based on self-assembly, the formation of discrete nano-sized supramolecules is enabled. [2] In contrast to weak interactions, which mostly are non-directional, the formation of ligandmetal dative bonds allows the rational design of novel structural motifs. [3] Special attention has been paid to the design of spherical containers with defined inner cavities. [4] Recently, we have shown that the pentaphosphaferrocene [Cp*Fe(h 5 -P 5 )] (1 a) (Cp* = h 5 -C 5 Me 5 ) acts with CuX (X = Cl, Br) as a building block for the formation of spherical supramolecules with the I h -C 80 fullerene-like topology consisting of 12 five-membered rings and 30 six-membered units (Figure 1, left). [5a,b] However, their synthesis is accompanied by polymeric products and special synthetic conditions have to be applied to avoid these products. [5c-f] In addition, most of the products are barely soluble in common solvents. Also a series of 90-vertex balls has been isolated which have a slightly better solubility (Figure 1, right). [5c-f] It is of note that almost all attempts to obtain spherical supramolecules from CuI and pentaphosphaferrocene failed to date. [6] Herein we report the synthesis and characterization of a nano-sized spherical supramolecule, obtained by the selfassembly of [Cp Bn Fe(h 5 -P 5 )] (1) (Cp Bn = h 5 -C 5 (CH 2 Ph) 5 ) and CuI, which shows a structure beyond the fullerene topology. Going from methyl to benzyl substituents at the Cp R ligand, the steric influence of the ligand to the metal center remains similar, [7] but the formation of an even larger spherical molecule is achieved for the first time. This compound does not show a fullerene topology despite having 12 five-membered rings derived from pentaphosphaferrocenes because there are no six-membered rings in the spherical scaffold. [8] In addition, the flexible organic groups of the Cp Bn ligand provide a good solubility of the resulting compound.
Unusually for this class of compounds 2 is soluble in CH 2 Cl 2 . Thus, NMR spectroscopic and mass spectrometric investigations have been carried out. The 1 H NMR spectrum shows broad signals for both the phenyl H atoms (d = 7.0-  Compound 2 crystallizes as deep red-brown blocks in the triclinic space group P1 The supramolecule occupies the center of symmetry. [9] Its idealized scaffold can be represented as a combination of eight {CuI 4  unit coordinates three molecules of 1 a. In addition, each cyclo-P 5 ligand of 1 is coordinated by two chelate {Cu 2 I} units. Therefore, each phosphorus atom is available for coordination to copper ions allowing an 1,2,3,4,5-coordination mode as in other pentaphosphaferrocene-based supramolecules. [5] Each of the (Cp Bn FeP 5 ) 2 (CuL)(Cu 2 I) 4 building blocks is connected to four {CuI 4 } tetrahedra and four other similar building blocks, which are rotated by 908 in two perpendicular directions (Figure 2 a). The building blocks are thus aggregated in an extended {CuI} 56 ladder-like framework by formation of Cu À I bonds (see Supporting Information), constructed of eight {CuI 4 } tetrahedra and 12 {Cu 4 I 2 } units, that can be found in some CuX frameworks. [10] The eight {CuI 4 } tetrahedra are arranged according to the corners of a giant "cube" with six (Cp Bn FeP 5 ) 2 (CuL)(Cu 2 I) 4 building blocks as the folded convex faces. The CuI-rich idealized scaffold constructed in this way has the formula [(Cp Bn FeP 5 ) 12 Cu 62 I 58 (MeCN) 4 ] and must be positively charged owing to the excess of copper ions (Figure 2 c). However, according to the diffraction data for the single crystals of 2, an average composition of (CH 2 Cl 2 ) 3.4 @[(Cp Bn FeP 5 ) 12 (CuI) 54 -(MeCN) 1.46 ]·2.54 MeCN·0.8 C 7 H 8 is obtained. It is chargebalanced because some copper, iodine, and coordinated acetonitrile positions are statistically vacant. The vacant positions are distributed such that each copper atom retains its tetrahedral environment and each iodide is two-, three-, or four-fold coordinated. The idealized ladder-like framework {CuI} 56 is thus reduced to its ordered part comprising of 34 copper and 40 iodine ions (Figure 2 d) with Cu À I bonds being in the range of 2.577(4)-2.800 (3) . 20 copper and 14 iodide ions statistically decorate the ordered part (see Supporting Information). The vacancies in some of copperion positions can vary the coordination mode of the cyclo-P 5 rings from the 1,2 and 1,2,3 found in the ordered {Cu 34 I 40 } part to the 1,2,3,4,5 mode that is achieved in the idealized structure. The Cu À P bonds vary in the range of 2.109(17) to 2.335(18) . The bonds FeÀP (2.345(8)-2.404 (7) ) and PÀP (2.071(10)-2.123 (11) ) are comparable to 2.37 and 2.11 , respectively, in the non-coordinated pentaphosphaferrocene. [7] Therefore, the crystal of 2 represents a solid solution of different similar supramolecules with the identical structural core comprising an ordered {Cu 34 I 40 } framework that predetermines the mutual spatial arrangement of 12 molecules of 1 as well as the shape of the supramolecule with an external size of 3.70 nm (Figure 2 b). They are the largest of the supramolecules built up by P n ligand complexes, being by 1.2 nm, 0.3 nm, and 0.64 nm, respectively, larger than [Cp*Fe-(h 5 -P 5 )]-containing spherical clusters. [5c,d, 6] For a more vivid comparison, the supramolecules in 2 are approximately 3.5 times larger in volume than the Buckminster fullerene C 60 . Even without the organic ligands, it is larger than the largest anionic copper(I) halide aggregate [Cu 36 I 56 ] 20À reported to date. [11] The supramolecules 2 have internal cavities of 0.75 nm, which is only 0.05 nm less in comparison to the 80-vertex supramolecule with 1 a as building block. [5b] The cavities incorporate an average of 3.4 molecules of CH 2 Cl 2 disordered over six possible positions (see Supporting Information). The surface of the inner cavities is formed by six idealized (Cp Bn FeP 5 ) 2 (CuL)(Cu 2 I) 4 building blocks that have folded convex geometry. Every guest molecule can occupy one of these six positions in the cavity oriented so that the Cl atoms point towards every idealized (Cp Bn FeP 5 ) 2 (CuL)(Cu 2 I) 4 building block according to the concave to convex principle (see Supporting Information). The intermolecular distances between the P atoms of the cyclo-P 5 rings and the Cl atoms of the guest molecule are about 3.8-3.9 , which correspond to weak van der Waals interactions.
The supramolecule 2 contains 4.5 CuI units per pentaphosphaferrocene. When the reaction is carried out with three or less equivalents of CuI, the polymeric by-product [{Cp Bn Fe-(h 5 -P 5 )} 2 {Cu 6 (m-I) 2 (m 3 -I) 4 }] n (3) can occasionally be observed [Equation (2)]. In contrast to 1 a as building block, the tendency for the formation of polymeric products is much lower for 1 and can completely be avoided by using a higher amount of CuI.
The 2D coordination polymer 3 crystallizes as yelloworange plates in the triclinic space group P1 . [9] It can easily be separated from the deep-red blocks of 2 either mechanically under the microscope or by washing the mixture with CH 2 Cl 2 , since 3 is insoluble in all common solvents. Single crystals of 3 were obtained from CH 2 Cl 2 /MeCN mixtures as solvate with one molecule CH 2 Cl 2 per repeating unit. The structure of 3 is built up by planar layers of building block 1, which binds to Cu 6 I 6 units in the rather uncommon 1,2,3,4-coordination mode. [12] The framework therefore comprises cyclo-P 5 ligands from the pentaphosphaferrocene, four-membered Cu 2 I 2 rings of the ladder, five-membered Cu 2 P 2 I rings, and six-membered Cu 2 P 4 rings ( Figure 3). The unit of 1 alternates up and down respective to the layer because of the bulky benzyl substituents. Hence, the layers are faced by the phenyl rings of Cp Bn . A coordination polymer with 1 a as building block and the same elemental formula was obtained earlier. [12] However, there the Cu 6 I 6 units are not arranged in a ladder, but in sixmembered rings instead. Hence, this demonstrates again the versatility of CuI in supramolecular and coordination chemistry.
In conclusion, the Cp Bn -substituted pentaphosphaferrocene 1 has proven to be a building block for unique spherical supramolecular aggregates. The replacement of Cp* by Cp Bn can reverse the tendency for the formation of polymeric instead of spherical coordination compounds. In addition, the Angewandte Chemie www.angewandte.org benzyl ligands provide unique solubility of the products that allowed the use of NMR and MS investigations. While polymeric products are favored in the case of 1 a, the reaction of 1 and six equivalents of CuI selectively leads to the formation of a gigantic supramolecule 2 featuring an unprecedented scaffold. The inorganic scaffold consists of cyclo-P 5 units and an expanded CuI framework with partial occupancies of few copper and iodine positions. It does not follow the fullerene-topology, because the CuI ladder structural motif provides no six-membered units, although twelve cyclo-P 5 rings are present. Having 180 heavy atoms in the scaffold and an outer diameter of 3.70 nm, 2 represents the largest discrete polynuclear complex built up either by five-fold symmetric building blocks or copper(I) halide aggregates. Received: July 11, 2014Revised: August 29, 2014 Published online: October 6, 2014 . Keywords: copper · Cp ligands · phosphorus · self-assembly · supramolecular chemistry