Influence of Volume on the Nucleation of Model Organic Molecular Crystals through an Induction Time Approach

Cruz, Isaac Jerome C. Dela; Perez, Jem Valerie D.; Alamani, Bryan G.; Capellades, Gerard; Myerson, Allan S.

doi:10.1021/acs.cgd.1c00101

Cited by 18 publications

(22 citation statements)

References 47 publications

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“…For TEM measurements, the samples are prepared by dropping 2.0 μL onto a 300 mesh copper grid coated with carbon. The grids were blotted on filter paper to avoid artifacts. , The induction time (τ) of nucleation was determined via the increasing turbidity of the solution and the appearance of the first crystal in a solution as detected by optical microscopy (AmScope 40X-2500X) …”

Section: Methodsmentioning

confidence: 99%

Influence of Taylor Vortex Flow on the Crystallization ofl-Glutamic Acid as an Organic Model Compound

Trinh

Nguyen

Khuu

et al. 2022

Ind. Eng. Chem. Res.

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The mechanism of polymorph selection is still not fully understood in crystallization. This study demonstrates the impact of Taylor vortex flow on the crystallization and polymorph selection of l-glutamic acid as an organic model compound. Our results show that amorphous intermediates preceded the formation of a crystalline phase. The morphology of these amorphous precursorsranging from spherical, oval, and ellipsoidal to irregular shapeswas governed by the velocity of the Taylor vortex flow. We attribute this observation to a transient liquidlike state of the amorphous precursor; simulations indeed corroborated this assumption as the morphology of droplets of a liquidlike precursor varies with the velocity of fluid motion accordingly. The phase selectivity depended on the intensity of the Taylor vortex flow. We found that the metastable α-form crystallized at low Taylor numbers, whereas the thermodynamically stable β-form was obtained at high Taylor numbers, suggesting an impact of Taylor vortex flow on the amorphous-to-crystalline rearrangement of the intermediates. Moreover, a critical value of the Taylor number as Ta ∼ 3636 was determined, which triggered the fast formation of the β-polymorph. We assume that the high shear rate and mass transfer of Taylor vortex flow facilitate the phase transformation from the α- to the β-polymorph.

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Section: Methodsmentioning

confidence: 99%

Influence of Taylor Vortex Flow on the Crystallization ofl-Glutamic Acid as an Organic Model Compound

Trinh

Nguyen

Khuu

et al. 2022

Ind. Eng. Chem. Res.

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“…Crystallization is a crucial unit operation in the pharmaceutical, food, and chemical industries that allows the generation of specialized solid materials with desired attributes such as purity, polymorphism, size distribution, and morphology. − Crystal morphology is one of the most important property indicators of pharmaceutical solids, as it could influence the performances of the products and subsequent downstream processing. − For example, needle-like crystals with a high aspect ratio raise difficulties in the blending stage and tableting process due to the poor flowability, tend to clog the equipment, and break easily. Flake-shaped crystals result in poor efficiency in filtering and washing since they tend to pack as an impermeable layer on the filter media.…”

Section: Introductionmentioning

confidence: 99%

Unveiling the Role of Additives in Modifying Crystallization Behaviors of 4-(Hydroxymethyl) Benzoic Acid

Cheng

Huang

Hao³

et al. 2022

Ind. Eng. Chem. Res.

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Additive-controlled crystallization is becoming an increasingly significant approach to controlling crystal morphology. In this study, to better understand the influence mechanism of additive on crystal morphology, 4-(hydroxymethyl) benzoic acid (p-HMBA) crystal crystallization behaviors with poly(vinylpyrrolidone) (PVP) were investigated by combing experiments and molecular simulations. Morphology of p-HMBA was modified from rod to block in the presence of PVP. It was seen that PVP would impede the crystal nucleation and growth. The inhibition effect of PVP on axial direction growth was much stronger than that on the radial direction. Molecular dynamics simulations revealed that the nucleation rate of p-HMBA crystal was inhibited due to the hydrogen-bonding interaction between PVP and p-HMBA molecules. The stronger interaction energy between PVP molecules and the (1 0 1̅) surface than that of the (0 1 0) surface might cause a stronger inhibition effect of PVP on the axial direction, which leads to the decline of the crystal aspect ratio.

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“…These authors observed a very strong increase of the nucleation rate in moving compared to static droplets, while somewhat lower nucleation rates were found in the stirred vials, despite a two orders of magnitude higher shear rate in the stirred vials. On a separate note, Dela Cruz et al concluded that changes in the shape of the probability distribution is an indication of the change in the nucleation regimes, which in most cases is caused by polymorphism, i.e., because of concomitant nucleation of two polymorphic forms or by transformation of a metastable into a more stable polymorph. A more extensive review of microfluidic induction time measurements can be found in following review articles. ,, …”

Section: Introductionmentioning

confidence: 99%

Microfluidic Platform with Serpentine Geometry Providing Chaotic Mixing in Induction Time Experiments

Shingte

Altenburg

Verheijen

et al. 2022

Crystal Growth & Design

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We present a droplet microfluidic platform mixing the contents of the droplet chaotically in microfluidic induction time measurements, a promising method for quantifying nucleation kinetics with minute amounts of solute. The nucleation kinetics of aqueous potassium chloride droplets dispersed in mineral oil without surfactants is quantified in the presence and absence of chaotic mixing. We demonstrate the ability of the proposed platform to dictate droplet size, to provide a homogeneous temperature distribution, and to chaotically mix the droplet contents. Chaotic mixing in induction time measurements is facilitated by the motion of droplets through serpentine micromixer bends, while the extent of mixing is controlled by how much droplets move. Different nucleation kinetics are observed in experiments where the droplets are static, mixed, and in motion. We hypothesize that the droplet motion induces formation of a thin-liquid Bretherton film surrounding the droplets. The thin film shields droplets from solid boundaries that are more efficient heteronucleant surfaces compared to liquid−liquid interfaces. We observed that repeated microfluidic induction time measurements, particularly with moving droplets, produce significantly distinct cumulative nucleation probability curves, indicating that the measured nucleation kinetics depend strongly on the details of the experimental procedure, which we discuss in detail. Finally, we compare the microfluidic experiments to well-mixed, milliliter volume, turbidity-based measurements in the context of classic nucleation theory.

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Influence of Volume on the Nucleation of Model Organic Molecular Crystals through an Induction Time Approach

Cited by 18 publications

References 47 publications

Influence of Taylor Vortex Flow on the Crystallization ofl-Glutamic Acid as an Organic Model Compound

Influence of Taylor Vortex Flow on the Crystallization ofl-Glutamic Acid as an Organic Model Compound

Unveiling the Role of Additives in Modifying Crystallization Behaviors of 4-(Hydroxymethyl) Benzoic Acid

Microfluidic Platform with Serpentine Geometry Providing Chaotic Mixing in Induction Time Experiments

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