Numerical Study of Soft Colloidal Nanoparticles Interaction in Shear Flow

Wilson, José Francisco; Kroupa, Martin; Košek, Juraj; Šoóš, Miroslav

doi:10.1021/acs.langmuir.8b03350

Cited by 7 publications

(6 citation statements)

References 39 publications

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“…In the past decades, DEM gained popularity, especially in modeling the dynamics of granular media, and also can be used for the modeling of particulate dispersions subjected to flow, allowing significantly higher number of simulated particles than SD because of the consideration of only pairwise interparticle interactions. In our previous works, we demonstrated that the DEM approach represents versatile and robust tool for the prediction of suspension coagulation dynamics and rheology in a good agreement with both theoretical expectations and experimental data. − Based on this knowledge, the present study serves as a proof-of-concept for CFD–DEM modeling of viscoelastic behavior of a particle suspension subjected to the oscillatory shear. The results of the model predictions characterize (i) effects of oscillatory shear on a suspending Newtonian fluid, and (ii) dependency of the suspension storage and loss moduli on various systems parameters.…”

Section: Introductionsupporting

confidence: 67%

Numerical Modeling of Viscoelasticity in Particle Suspensions Using the Discrete Element Method

et al. 2019

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The rheological behavior of particle suspensions is a challenging problem because its description depends on the interaction of two phases with different material properties. This interaction can lead to complex behavior because of acting forces at the solid–liquid interface such as lubrication. The goal of this work is to propose a method for the modeling of fluids viscoelasticity in the presence of spherical particles including fluid–particle interactions. To accomplish this, we employed a simplified approach using the discrete element method (DEM) coupled with computational fluid dynamics (CFD) to simulate a suspension of particles under oscillatory flow in a three-dimensional computational domain. The choice of DEM provides versatility to customize the constitutive relations of particle–particle and fluid–particle interactions. Particularly, we focused on studying the effect of solid–liquid interaction (lubrication forces) on the viscoelasticity of the particulate system. To analyze the effect of this interfacial force, we simplified the particle–particle interaction to a nonadhesive elastic contact, thus avoiding aggregation of the particles. The work consists of two parts: the first one is a pure CFD model of the oscillatory motion applied to a Newtonian fluid (without particles), and the second is an extended version including DEM to simulate the viscoelasticity of the particle suspension. In this way, we can isolate the effect of fluid inertia on the viscoelasticity of the particulate system. The obtained results show that the model is capable to reproduce qualitatively the increase of the storage modulus as a function of the solid volume fraction and the dependence of dynamic moduli on the applied shear strain. The presented methodology provides a new insight into modeling of rheology by customizing interactions at the particle level based purely on first-principles with model parameters including solely material properties and physically identifiable quantities.

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Section: Introductionsupporting

confidence: 67%

Numerical Modeling of Viscoelasticity in Particle Suspensions Using the Discrete Element Method

et al. 2019

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“…In general, in addition to providing high shear rates, such systems allow better control of process variables such as temperature, flow rates, residence times, and reagents ratios [79][80][81]. From the mechanistic viewpoint, recent studies have provided additional evidence that correlated the success of these synthesis devices with the control of advection, nucleation, and growth processes [64,82,83]. This high level of control over such phenomena has been thought to directly impact the nucleation and subsequent growth of the nanoparticles.…”

Section: Discussionmentioning

confidence: 99%

“…This is most likely due to the narrower channels and the abrupt direction changes observed for the reaction mixture in this case. Different levels of shear rate have been reported to strongly impact the NPs' nucleation and growth processes [64,65]. Figure 6 shows the shear rates for each micromixer.…”

Section: Microfluidic Cfd Simulationmentioning

confidence: 99%

CFD Analysis and Life Cycle Assessment of Continuous Synthesis of Magnetite Nanoparticles Using 2D and 3D Micromixers

et al. 2022

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Magnetite nanoparticles (MNPs) have attracted basic and applied research due to their immense potential to enable applications in fields as varied as drug delivery and bioremediation. Conventional synthesis schemes led to wide particle size distributions and inhomogeneous morphologies and crystalline structures. This has been attributed to the inability to control nucleation and growth processes under the conventional conditions of bulk batch processes. Here, we attempted to address these issues by scaling down the synthesis process aided by microfluidic devices, as they provide highly controlled and stable mixing patterns. Accordingly, we proposed three micromixers with different channel configurations, namely, serpentine, triangular, and a 3D arrangement with abrupt changes in fluid direction. The micromixers were first studied in silico, aided by Comsol Multiphysics® to investigate the obtained mixing patterns, and consequently, their potential for controlled growth and the nucleation processes required to form MNPs of uniform size and crystalline structure. The devices were then manufactured using a low-cost approach based on polymethyl methacrylate (PMMA) and laser cutting. Testing the micromixers in the synthesis of MNPs revealed homogeneous morphologies and particle size distributions, and the typical crystalline structure reported previously. A life cycle assessment (LCA) analysis for the devices was conducted in comparison with conventional batch co-precipitation synthesis to investigate the potential impacts on water and energy consumption. The obtained results revealed that such consumptions are higher than those of the conventional process. However, they can be reduced by conducting the synthesis with reused micromixers, as new PMMA is not needed for their assembly prior to operation. We are certain that the proposed approach represents an advantageous alternative to co-precipitation synthesis schemes, in terms of continuous production and more homogeneous physicochemical parameters of interest such as size, morphologies, and crystalline structure. Future work should be directed towards improving the sustainability indicators of the micromixers’ manufacturing process.

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“…Moreover, in previous articles, we have found a direct relation between interparticle adhesion and the size of formed nanoparticle aggregates. 15,27,30 Using the previously described numerical tools, the relationship for the adhesive force between nanoparticles and the size of the formed fractal aggregates will be investigated under various shear flow conditions. Particularly, three hypotheses will be studied in order to understand the evolution of aggregate size with the shear rate at temperatures above the polymer shell T g .…”

Section: ■ Materials and Methodsmentioning

confidence: 99%

“…The main considerations taken into account by Marshall are to include the particle concentration field and the body force exerted by the particles into the flow field calculation. This approach has been used in several of our previous articles. ,− The resulting velocities calculated from the modified N–S equations are then used as an input to calculate the forces affecting each particle. The most relevant forces affecting nanoparticles dispersed in fluids are drag, buoyancy, gravity, van der Waals attraction, electrostatic repulsion, and the force arising from physical NP contact.…”

Section: Methodsmentioning

confidence: 99%

Study of the Shear-Thinning Effect between Polymer Nanoparticle Surfaces during Shear-Induced Aggregation

Wilson

Zahradník

Šrom

et al. 2021

Ind. Eng. Chem. Res.

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In this research, we studied the impact of material fusion as an adhesion mechanism on the size and structure of fractal aggregates formed during shear aggregation of fully destabilized polymer nanoparticles (NPs). The nanoparticles have a core–shell structure, where the core is composed of poly(methyl methacrylate) (PMMA) and the shell consists of a combination of PMMA and polybutyl acrylate (PBA). Due to significantly different glass transition temperatures (T g ’s) of these polymers, the core acts as a hard sphere, while the presence of PBA in the shell gives the surface a soft character. By varying the system temperature, material fusion is induced between the particles in contact. The strength of the formed physical bond is tested under various shear rate conditions. It was found that the increase in temperature leads to an increase in aggregate size, caused by an increase in adhesion between NP surfaces. This phenomenon occurs due to a material softening of the polymer shell triggered by the increase in temperature, resulting in the formation of a viscous sticky surface. Additionally, it was observed that at temperatures above the T g of the polymer composing the shell, the increase in the shear rate causes a reduction of the interparticle contact strength suggesting a shear-thinning effect during contact. The interplay between these two contradicting mechanisms determines the final mechanical properties of produced material.

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Numerical Study of Soft Colloidal Nanoparticles Interaction in Shear Flow

Cited by 7 publications

References 39 publications

Numerical Modeling of Viscoelasticity in Particle Suspensions Using the Discrete Element Method

Numerical Modeling of Viscoelasticity in Particle Suspensions Using the Discrete Element Method

CFD Analysis and Life Cycle Assessment of Continuous Synthesis of Magnetite Nanoparticles Using 2D and 3D Micromixers

Study of the Shear-Thinning Effect between Polymer Nanoparticle Surfaces during Shear-Induced Aggregation

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