COMPLEMENTARY SHAPES IN COLUMNAR LIQUID-CRYSTALS - STRUCTURAL CONTROLIN HOMONUCLEAR AND HETERONUCLEAR BIMETALLIC ASSEMBLIES

A comprehensive study of the liquid-crystalline properties of 51 bimet allic compounds based upon 1,3,5-triketonate and 1,3,5,7-tetraketonate ligands is reported. These materials are liquid crystalline when six or more side chains are appended to the mesogenic core, and only colum nar phases were observed. Most of the liquid crystals were homonuclear dicopper complexes. Schiff-base derivatives of some of the triketones allowed for the synthesis of heteronuclear bimetallic liquid crystals . The NiCu and NiPd Schiff-base complexes are the first heteronuclear liquid crystals with proximate (strongly interacting) metal centers. O ther heteronuclear complexes investigated were not liquid crystalline due to the tendency to retain coordinated solvent or to form strongly associated structures in the absence of axial ligands. The use of comp lementary shapes was demonstrated as a means to generate average relat ive organizations (correlations) between the complexes. The presence o f these correlated structures was shown through comparisons of the str uctures, phase behavior, and the immiscibility between materials havin g the same phase but different shapes. Correlated structures were show n which produce average rotations of 90-degrees and 180-degrees betwee n nearest-neighbor molecules. A crystal structure of one compound conf irmed that a similar superstructure was exhibited in the solid state. In addition, it was found that the correlated structures exhibit relat ively short (3.29 angstrom) correlations between the mesogens, thereby allowing for strong intermolecular interactions. The ability to contr ol the orientation and relative position of transition metal centers i n liquid crystals has applications in the design of new liquid-crystal line materials with useful magnetic and electronic properties.