Ingo Bernt

Ligand-to-metal ratio controlled assembly of tetra- and hexanuclear clusters towards single-molecule magnets.

A simple template-mediated route, starting from triethalolamine 1, sodium hydride or caesium carbonate, and iron(III) chloride led to the six- and eight-membered iron coronates [Na c [Fe6[N(CH2CH2O)3]6]]+ (2) and [Cs c (Fe8[N(CH2CH2O)3]8]]+ (3). In the reaction of N-methyldiethanolamine 4 (H2L1) or N-(2,5-dimethylbenzyl)iminodiethanol 6 (H2L2) with calcium hydride followed by addition of a solution of iron(III) chloride, the neutral unoccupied coronands [Fe6Cl6(L1)6] (5) and [Fe6Cl6(L2)6] (7) were formed. Subsequent exchange of the chloride ions of 7 by bromide or thiocyanate ions afforded the ferric wheels [Fe6Br6(L2)6] (8) or [Fe6(NCS)6(L2)6] (9), respectively. Titration experiments of solutions of dianion (L1)2- with iron(III) chloride in THF revealed interesting mechanistic details about the self-assembling process leading to 5. At an iron/ligand ratio of 1:1.5 star-shaped tetranuclear [Fe[Fe(L1)2]3] (11) was isolated. However, at an iron/ligand ratio of 1:2, complex 11 was transformed into the ferric wheel 5. It was shown, that the interconversion of 5 and 11 is reversible. Based on the mechanistic studies, a procedure was developed which works for both the synthesis of homonuclear 11 and the star-shaped heteronuclear clusters [Cr[Fe(L1)2]3] (12) and [Al[Fe(L1)2]3] (13). The structures of all new compounds were determined unequivocally by single-crystal X-ray analyses.

The {FeIII[FeIII(L1)2]3} star-type single-molecule magnet

Star-shaped complex {FeIII[FeIII(L1)2]3} (3) was synthesized starting from N-methyldiethanolamine H2L1 (1) and ferric chloride in the presence of sodium hydride. For 3, two different high-spin iron(III) ion sites were confirmed by Mossbauer spectroscopy at 77 K. Single-crystal X-ray structure determination revealed that 3 crystallizes with four molecules of chloroform, but, with only three molecules of dichloromethane. The unit cell of 3·4CHCl3 contains the enantiomers (Δ)-[(S,S)(R,R)(R,R)] and (Λ)-[(R,R)(S,S)(S,S)], whereas in case of 3·3CH2Cl2 four independent molecules, forming pairs of the enantiomers [Λ-(R,R)(R,R)(R,R)]-3 and [Δ-(S,S)(S,S)(S,S)]-3, were observed in the unit cell. According to SQUID measurements, the antiferromagnetic intramolecular coupling of the iron(III) ions in 3 results in a S = 10/2 ground state multiplet. The anisotropy is of the easy-axis type. EPR measurements enabled an accurate determination of the ligand-field splitting parameters. The ferric star 3 is a single-molecule magnet (SMM) and shows hysteretic magnetization characteristics below a blocking temperature of about 1.2 K. However, weak intermolecular couplings, mediated in a chainlike fashion via solvent molecules, have a strong influence on the magnetic properties. Scanning tunneling microscopy (STM) and scanning tunneling spectroscopy (STS) were used to determine the structural and electronic properties of star-type tetranuclear iron(III) complex 3. The molecules were deposited onto highly ordered pyrolytic graphite (HOPG). Small, regular molecule clusters, two-dimensional monolayers as well as separated single molecules were observed. In our STS measurements we found a rather large contrast at the expected locations of the metal centers of the molecules. This direct addressing of the metal centers was confirmed by DFT calculations.

Synergistic Effect of Serendipity and Rational Design in Supramolecular Chemistry

Many of the higher nuclearity Werner-type clusters are fortuitous discoveries. This clearly suggests that the principles which control cluster formation are still poorly understood from the point of view of rational design. However, the predictable nature of coordination chemistry has been used successfully for the specific generation of the metalla-topomers of the well-known organic-based coronates and cryptates. Furthermore, it has been shown that the metal coordination geometry and the orientation of the interacting sites in a given ligand provide the instruction, or blueprint, for the rational design of high symmetry coordination clusters. Based on these principles, and the interplay with serendipity, directed syntheses for polynuclear metalla-coronates, sandwich complexes, manifold metalla-cryptates, and metalla-cylinders have been developed. Only recently, the combination of detailed symmetry considerations with the basic protocols of coordination chemistry have made the design of rational strategies for the construction of a variety of nanoscale systems with procured shape and size feasible. Highlights among these species are cube-like clusters and multicompartmental cylindrical nanostructures.

Ligand and metal controlled multicomponent self-assembly of oligonuclear two- and three-dimensional complex molecular architectures

Abstract Significant advances have been made in the rational design and characterisation of homo- and hetero-oligonuclear 2D- and 3D-supramolecular structures. Multidisciplinary studies of these new materials are of great promise with respect to catalysis, ion transport, molecular recognition and magnetic and optical characteristics. Furthermore, these well defined clusters may serve as model compounds for the understanding of charge transport processes in biological systems.