Dottorato di Ricerca in Scienza e Tecnologia dei Materiali
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Prof. Susan Bourne

Professore Ordinario

Tel: +27 21 650 2563 Email:
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• Dottorato di Ricerca in Scienza e Tecnologia dei Materiali


The concept of crystal engineering has provided a useful framework to develop rational approaches to solid-state structural design based on the self-assembly of molecular components.  This field uses the concepts first developed in supramolecular chemistry; in particular recognizing the importance of hydrogen bonding, p¼p  interactions and other “weak” interactions in generating and stabilizing larger networks.    Of particular interest for their diverse functional properties are the “metal organic frameworks” or MOFs (porous polymeric materials, consisting of metal ions linked by organic bridging ligands) and layered hybrid perovskites (in which layers of metal centres are separated by organic layers with no covalent bonds linking the layers).

These materials are of interest because of their structural, magnetic, optical and electrical properties, particularly since these can be easily modified by replacement of the metal, halide or amine.  The tendency of the hybrids to self-assemble from the solid or liquid phase arises from the range of interactions seen in these compounds, from van der Waals forces between organic components, hydrogen bonding within the organic layer or between organic and inorganic components to ionic and covalent bonds within the metal halide sheets.

We have a fruitful collaboration with Prof Klaus Koch (University of Stellenbosch) on the self-assembly of metallomacrocyclic complexes. Using thiourea derived ligands to form metallomacrocyclic complexes of platinum(II) or nickel(II), whose sizes (2:2 or 3:3 metal:ligand) depend only on the relative substitution (para vs meta) of the carbylthiourea moieties linked through a phenylene ring, we have explored the crystal engineering and inclusion properties of such metallomacrocycles.  The Ni(II) example is interesting as it is readily converted to octahedral geometry through the coordination of two axial ligands perpendicular to the macrocycle plane.

Struttura di afferenza:
Centre for Supramolecular Chemistry Research, University of Cape Town

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Ultimo aggiornamento: 01/04/2015 11:34