CM1402 Crystallize COST Overview
COST Action CM1402 Chemistry and Molecular Sciences and Technologies
From Molecules to Crystals - how do Organic Molecules form Crystals (Crystallize)?
Typically during chemical manufacturing, crystallization is employed as a purification step, or to isolate the final product. Crystallization determines the quality of the product obtained but understanding the molecular mechanisms which occur during crystallization remains a scientific challenge, particularly for Organic compounds.
Developments in advanced analytical techniques, molecular recognition probes and computational methodologies are beginning to provide insight into how molecules interact in solution, aggregate and, ultimately, form crystals. Together with studies in different phases, in confined systems, on surfaces and with impurities, this will improve our understanding of Crystallization processes. The EU plays host to recognised global leaders in different aspects of Crystallization which, when brought together, are in a unique position to drive the molecular understanding of the Crystallization process.
Crystal engineering has advanced so that there is understanding of the supramolecular interactions in molecular solids. The next step is to fully understand structure/function relationships in order to custom design new materials for specific applications. European researchers need to embrace this new paradigm in materials design, combine it with the developing insights into the crystallization processes, and exploit both of these to control crystallization processes with increased product yield and purity, and also reduced environmental impact and cost.
Compounds of special interest to the Sction members include: Chiral Compounds, Diflusisal, Glycine, Host Guest Compounds, Hydroxyacetophenone, Isonicotinamide, Levetiracetam (Etiracetam), Norleucin, Peptides (in the solid state), Statins and Sulphonamidesindomethacin.