Crystallization mechanisms of acicular crystals

In this contribution, we present an experimental investigation of the growth of four different organic molecules produced at industrial scale with a view to understand the crystallization mechanism of acicular or needle-like crystals. For all organic crystals studied in this article, layer-by-layer...

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Bibliographic Details
Published in:Journal of crystal growth 2008-01, Vol.310 (1), p.110-115
Main Authors: Puel, François, Verdurand, Elodie, Taulelle, Pascal, Bebon, Christine, Colson, Didier, Klein, Jean-Paul, Veesler, Stéphane
Format: Article
Language:English
Subjects:
A1. Crystal morphology
A2. Growth from solutions
B1. Organic compounds
Condensed matter: structure, mechanical and thermal properties
Cross-disciplinary physics: materials science
rheology
Equations of state, phase equilibria, and phase transitions
Exact sciences and technology
General studies of phase transitions
Growth from solutions
Materials science
Methods of crystal growth
physics of crystal growth
Nucleation
Physics
Solid-solid transitions
Specific phase transitions
Theory and models of crystal growth
physics of crystal growth, crystal morphology and orientation
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Summary:In this contribution, we present an experimental investigation of the growth of four different organic molecules produced at industrial scale with a view to understand the crystallization mechanism of acicular or needle-like crystals. For all organic crystals studied in this article, layer-by-layer growth of the lateral faces is very slow and clear, as soon as the supersaturation is high enough, there is competition between growth and surface-activated secondary nucleation. This gives rise to pseudo-twinned crystals composed of several needle individuals aligned along a crystallographic axis; this is explained by regular over- and inter-growths as in the case of twinning. And when supersaturation is even higher, nucleation is fast and random. In an industrial continuous crystallization, the rapid growth of needle-like crystals is to be avoided as it leads to fragile crystals or needles, which can be partly broken or totally detached from the parent crystals especially along structural anisotropic axis corresponding to weaker chemical bonds, thus leading to slower growing faces. When an activated mechanism is involved such as a secondary surface nucleation, it is no longer possible to obtain a steady state. Therefore, the crystal number, size and habit vary significantly with time, leading to troubles in the downstream processing operations and to modifications of the final solid-specific properties. These results provide valuable information on the unique crystallization mechanisms of acicular crystals, and show that it is important to know these threshold and critical values when running a crystallizer in order to obtain easy-to-handle crystals.
ISSN:0022-0248
1873-5002
DOI:10.1016/j.jcrysgro.2007.10.006