Population Balance Modeling of Growth and Secondary Nucleation by Attrition and Ripening

Bosetti, Luca; Mazzotti, Marco

doi:10.1021/acs.cgd.9b01240

Cited by 33 publications

(44 citation statements)

References 35 publications

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“…118 nucleation rates are given by an empirical relationship that depends on the number of suspended crystals (volume or surface), the level of supersaturation (either directly or through growth rate), and the degree of mixing (usually through average energy dissipation). 48 The rate of secondary nucleation increases with the increase of these three quantities. 113 Secondary nucleation is an autocatalytic process that significantly affects the crystallization outcome, such as the CSD, polymorphism, and chirality of the crystal products.…”

Section: Effect Of Secondary Nucleation On Crystallization Outcomementioning

confidence: 95%

“…These fragments then grow or dissolve depending on the degree of supersaturation in the system. 48 Bosetti and Mazzotti 49 conducted attrition experiments in ethanol at different stirring speeds, and the results showed that by increasing energy input, nuclei appeared faster and in greater quantities. Synowiec et al 50 studied the attrition of potassium alum in the presence of an antisolvent (ethanol) and established a model that takes into account the fine particles formed due to the turbulent nature of the flow field.…”

Section: Introductionmentioning

confidence: 99%

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Overview of Secondary Nucleation: From Fundamentals to Application

Hou

Chuai

et al. 2020

Ind. Eng. Chem. Res.

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Secondary nucleation can bring the crystallization process into a more easily controlled state, and it is playing an important role in controlling crystal size distribution, polymorphism, and chirality of the crystal products, no matter whether in a batch or continuous crystallizer. Therefore, in this review, we revisit the research of secondary nucleation in the past 30 years to understand the fundamentals and application of secondary nucleation. First, we summarize the sources of secondary nuclei, that is, how secondary nucleation occurs. Then, we discuss the secondary nucleation threshold from the perspective of the metastable zone widths which are associated with the nucleation mechanism. Furthermore, we discuss how to employ secondary nucleation to regulate the properties of crystalline products (particle size distribution, crystal polymorphism, chirality, etc.). More importantly, we also discuss how polymorphism and chirality can act as a probe to explore the origin of secondary nucleation. Finally, we give conclusions and outlooks, mainly on the molecular nucleation mechanism and crystal growth dead zone of the current topic of secondary nucleation.

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Section: Effect Of Secondary Nucleation On Crystallization Outcomementioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Overview of Secondary Nucleation: From Fundamentals to Application

Hou

Chuai

et al. 2020

Ind. Eng. Chem. Res.

View full text Add to dashboard Cite

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“…As far as r is concerned, there are two limit behaviors, whereby ϵ(0) ≃ 0 and ϵ( r → ∞) ≃ 1, and two threshold values, namely, the just suspended and the uniformly suspended cases. It is worth noting in passing that for very intense stirring, i.e., for r → ∞, secondary nucleation will be controlled by the attrition mechanism, 48 whereby the role of SNIPE will be negligible.…”

Section: Methodsmentioning

confidence: 99%

Secondary Nucleation by Interparticle Energies. III. Nucleation Rate Model

Ahn

Bosetti

Mazzotti

2022

Crystal Growth & Design

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A nucleation rate model for describing the kinetics of secondary nucleation caused by interparticle energies (SNIPEs) is derived theoretically, verified numerically, and validated experimentally. The theoretical derivation reveals that the SNIPE mechanism can be viewed as enhanced primary nucleation, i.e., primary nucleation with a lower thermodynamic energy barrier (for nucleation) and a smaller critical nucleus size, both caused by the interparticle interactions and the associated energy between the surface of a seed crystal and a molecular cluster in solution, as shown in part I of this series. In the case of a sufficiently agitated suspension, the model depends on four parameters: two reflecting primary nucleation kinetics and the other two accounting for the intensity and effective spatial range of the interparticle interactions. As a numerical verification of the model, we show that the nucleation kinetics described by the SNIPE rate model is in quantitative agreement with those given by the kinetic rate equation model developed in part II of this series. A sensitivity analysis of the SNIPE rate model is conducted to present the effect of key model parameters on the nucleation kinetics. Moreover, the SNIPE rate model is validated by fitting the model to the time-resolved data of secondary nucleation experiments as well as to two other, well-known secondary nucleation rate models. Importantly, all of the estimated parameter values for the SNIPE model were consistent with the theoretical estimates, while some of the estimated parameter values for one of the well-known secondary nucleation models deviated from the corresponding theoretical values significantly.

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“…The latter mechanism must clearly be prevented, namely, by keeping the supersaturation level below a (secondary nucleation-) specific threshold, which is even lower than the previous one. Such physical complexity is accounted for in the model by allowing for the formation of new nuclei of the desired enantiomer via secondary nucleation by attrition, 41 as described in Table 2 , and by constraining the simulations in such a way that the supersaturation with respect to the undesired enantiomer is kept below a given threshold, so as to avoid both its secondary and its primary nucleation. To model the mechanisms that occur in this process in a simple manner, both breakage and the formation of new nuclei of the desired enantiomer by secondary nucleation can be described as secondary nucleation via attrition by a simple breakage model, 41 as Table 2 describes.…”

Section: Process Designmentioning

confidence: 99%

Solid-State Deracemization via Temperature Cycles in Continuous Operation: Model-Based Process Design

Bodák

Mazzotti

2022

Crystal Growth & Design

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Solid-state deracemization via temperature cycles converts a racemic crystal mixture into an enantiopure product by periodic cycling of the temperature in the presence of a racemization catalyst. A continuous counterpart of this conventional batch-operated process is proposed that can be performed in mixed suspension mixed product removal crystallizers (MSMPRCs). More specifically, three different configurations are described to perform periodic forcing via temperature cycles, which differ from each other in the type of the feed and in the withdrawal system. We have developed a model by extending our recent population balance equation model of batch solid-state deracemization via temperature cycles, and we exploit this tool to analyze the start-up and periodic steady-state behavior. Moreover, we compare the performance of the different configurations based on the selected key performance indicators, namely, average periodic steady-state enantiomeric excess and productivity. The process with solution feed yields pure enantiomers, while the solid and suspension-fed process alternatives result in highly enantiomerically enriched crystals. We further design an MSMPRC cascade to overcome this purity limitation. This work discusses guidelines on how to transform the batch process of temperature cycles into a continuous operation, which enables stable, unattended operation and chiral crystal production with consistent product quality.

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Population Balance Modeling of Growth and Secondary Nucleation by Attrition and Ripening

Cited by 33 publications

References 35 publications

Overview of Secondary Nucleation: From Fundamentals to Application

Overview of Secondary Nucleation: From Fundamentals to Application

Secondary Nucleation by Interparticle Energies. III. Nucleation Rate Model

Solid-State Deracemization via Temperature Cycles in Continuous Operation: Model-Based Process Design

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