TY - JOUR

T1 - Computer simulation of crystallization from solution

AU - Anwar, J

AU - Boateng, PK

PY - 1998/9/23

Y1 - 1998/9/23

N2 - The early stages of crystallization are not fully understood, a particularly challenging problem being crystallization from solution. The processes involved at an atomic level remain elusive to experiment. Furthermore, crystallization from solution has been thought to be inaccessible by atomistic computer simulations. This study demonstrates that crystallization from solution can in fact be simulated using the method of molecular dynamics for a model solute/solvent system consisting of atomic species characterized by the Lennard-Jones potential function. The model has been applied to look at the effects of varying supersaturation and of inclusion of a simple inhibitor in the system. The behavior of the model is in accord with experiment. In general, increasing supersaturation causes earlier onset of crystallization. Crystallization in highly supersaturated systems involves liquid-liquid phase separation followed by nucleation in the solute phase. The nucleation event in such systems does not appear to be influenced by the solvent. Inclusion of inhibitors retards the onset. Additionally, extensive solute clustering is observed. The crystallization model and variations on it, as well as step by step extension to realistic systems, should enable further testing and development of theory of crystal nucleation and growth and provide insights of technological importance.

AB - The early stages of crystallization are not fully understood, a particularly challenging problem being crystallization from solution. The processes involved at an atomic level remain elusive to experiment. Furthermore, crystallization from solution has been thought to be inaccessible by atomistic computer simulations. This study demonstrates that crystallization from solution can in fact be simulated using the method of molecular dynamics for a model solute/solvent system consisting of atomic species characterized by the Lennard-Jones potential function. The model has been applied to look at the effects of varying supersaturation and of inclusion of a simple inhibitor in the system. The behavior of the model is in accord with experiment. In general, increasing supersaturation causes earlier onset of crystallization. Crystallization in highly supersaturated systems involves liquid-liquid phase separation followed by nucleation in the solute phase. The nucleation event in such systems does not appear to be influenced by the solvent. Inclusion of inhibitors retards the onset. Additionally, extensive solute clustering is observed. The crystallization model and variations on it, as well as step by step extension to realistic systems, should enable further testing and development of theory of crystal nucleation and growth and provide insights of technological importance.

KW - DESIGN

KW - LENNARD-JONES SYSTEM

KW - MECHANISM

KW - CRYSTAL NUCLEATION

KW - ENERGY

KW - COLLOIDAL SPHERES

KW - PHASE

KW - MOLECULAR-DYNAMICS

U2 - 10.1021/ja972750n

DO - 10.1021/ja972750n

M3 - Journal article

VL - 120

SP - 9600

EP - 9604

JO - Journal of the American Chemical Society

JF - Journal of the American Chemical Society

SN - 0002-7863

IS - 37

ER -