Molecular level simulations on multi-component systems —a morphology prediction method

C. SCHMIDT; J. ULRICH

doi:10.1007/s11705-013-1307-8

PDF(326 KB)

Front. Chem. Sci. Eng. ›› 2013, Vol. 7 ›› Issue (1) : 49-54. DOI: 10.1007/s11705-013-1307-8

RESEARCH ARTICLE

Molecular level simulations on multi-component systems —a morphology prediction method

C. SCHMIDT ,
J. ULRICH

Author information +

History +

Abstract

The crystal morphology grown from a solution composed of an organic solvent, solute and additive can be predicted reliably by a computational method. Modeling the supersaturated solution as liquid phase is achieved by employing commercial software. The molecular composition of this solution is a required input parameter. The face specific diffusion coefficient of the solid (crystal surface) and liquid (solution) system is determined using the molecular dynamics procedure. The obtained diffusion coefficient is related to the specific face growth rate via the attachment energy of the pure morphology. The significant improvements are achieved in the morphology prediction because the investigation on the face growth rates in a complex growth environment (as multi-component solutions with additives) can be carried out based on the diffusion coefficients.

Keywords

crystallization / morphology / molecular dynamics / solution

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

C. SCHMIDT, J. ULRICH. Molecular level simulations on multi-component systems —a morphology prediction method. Front Chem Sci Eng, 2013, 7(1): 49‒54 https://doi.org/10.1007/s11705-013-1307-8

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Accelrys Software Inc. MaterialsStudio 4.0, San Diego, USA, 2005

[2]	Bravais A. Etudes Crystallographiques. Paris: Gauthier-Villars, 1866

[3]	Friedel M G. Etudes Sur la Loi de Bravais. Bulletin de la Société Française de Minéralogie, 1907, 30: 326–445

[4]	Donnay J D, Harker D. A new law for crystal morphology extending the law of Bravais. American Mineralogist, 1938, 22: 457–477

[5]	Hartman P, Bennema P. The attachment energy as a habit controlling factor I–III. Journal of Crystal Growth, 1980, 49: 145–170

[6]	Niehörster S, Ulrich J. Designing crystal morphology by a simple approach. Crystal Research and Technology, 1995, 30(3): 389–395 CrossRef Google scholar

[7]	Lu J J, Ulrich J. Improved understanding of molecular modelling—the importance of additive incorporation. Journal of Crystal Growth, 2004, 270(1-2): 203–210 CrossRef Google scholar

[8]	Schmidt C, Ulrich J. Predicting crystal morphology grown from solution. Chemical Engineering Technology, 2012, 35: 1009–1012

[9]	Schmidt C, Ulrich J. Crystal habit prediction—including the liquid as well as the solid side. Crystal Research and Technology, 2012, 47(6): 597–602 CrossRef Google scholar

[10]	Schmidt C. Predicting the crystal morphology grown from aqueous solution. Dissertation for the Doctoral Degree. Halle: Martin Luther University Halle-Wittenberg, 2012

[11]	Leviel J L, Auvert G, Savariault J M. Hydrogen bond studies. A neutron diffraction study of the structures of succinic acid at 300 K and 70 K. Acta Crystallographica, 1981, B37: 2185–2189

[12]	Maple J R, Dinur U, Hagler A T. Derivation of force fields for molecular mechanics and dynamics from ab initio energy surfaces. Proceedings of the National Academy of Sciences of the United States of America, 1988, 85(15): 5350–5354 CrossRef Pubmed Google scholar

[13]	Lemmer S, Ruether F. Habit prediction of succinic acid influenced by two solvents using build-in method. Crystal Research and Technology, 2012, 77: 143–149