Lattice Boltzmann modelling of colloidal suspensions drying in porous media accounting for local nanoparticle effects

Qin, Feifei; Fei, Linlin; Zhao, Jianlin; Kang, Qinjun; Derome, Dominique; Carmeliet, Jan

doi:10.1017/jfm.2023.344

Cited by 15 publications

(6 citation statements)

References 75 publications

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“…LBM has been successfully applied to model the drying of colloidal suspensions, enhancing heat conduction in nanoparticle deposition, which is analogous to the fine control required in CVD processes [75].…”

Section: Lattice Boltzmann Methods (Lbm)mentioning

confidence: 99%

Recent Progress in Heat and Mass Transfer Modeling for Chemical Vapor Deposition Processes

Łach,

Svyetlichnyy

2024

Preprint

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Chemical vapor deposition (CVD) is a vital process for depositing thin films of various materials with precise control over thickness, composition, and properties. Understanding the heat and mass transfer mechanisms during CVD is essential for optimizing process parameters and ensuring high-quality film deposition. This review provides an overview of recent advancements in the heat and mass transfer modeling for chemical vapor deposition processes. It explores innovative modeling techniques, recent research findings, emerging applications, and challenges in the field. Additionally, it discusses future directions and potential areas for further advancement in CVD modeling.

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Section: Lattice Boltzmann Methods (Lbm)mentioning

confidence: 99%

Recent Progress in Heat and Mass Transfer Modeling for Chemical Vapor Deposition Processes

Łach,

Svyetlichnyy

2024

Preprint

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“…The emerging agglomeration is usually connected with potential materials discontinuity, which negatively influences the mechanical properties. The most problematic area is the joint between the asphalt and aggregate and their adhesion [55,56].…”

Section: Micro and Nano-additives Dispersionmentioning

confidence: 99%

An Overview of Micro- and Nano-Dispersion Additives for Asphalt and Bitumen for Road Construction

Korniejenko,

Nykiel,

Choinska

et al. 2023

Buildings

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The main motivations for the development of research in the area of appropriate additives for asphalt and bitumen are the enhancement of their properties and improvement of their production process, including the reduction in environmental burden. Many additives improve the properties of mineral–asphalt mixtures. Traditionally, additives such as the following are applied: elastomers, plastomers, latexes, rubber powder, resins, and others. Currently, the modification of asphalt and bitumen materials by traditional additives can be replaced by nanomaterials that better fit the requirements of modern industry. New solutions are required, which has led to years of studies researching micro- and nano-additives. The main aim of the article is to analyze contemporary research where micro- and nano-additives were applied to asphalt and bitumen and summarize the advantages and disadvantages of the implementation of these additives for road construction. The article studied the state of the art in this area based on the literature research. It presents the possible materials’ solutions, including their properties, used technology, and featured trends for road construction. The challenges for further projects are discussed, especially environmental issues.

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“…At the pore scale, there are two types of numerical simulation methods: the direct numerical simulation (DNS) method and pore network model (PNM) . The computational fluid dynamics (CFD) method , and lattice Boltzmann method (LBM) − are the most commonly used DNS methods, which solve the Navier–Stokes (N–S) equation directly in the real pore structures . Gurumurthy et al and Zhao et al analyzed the imbibition dynamics in a single square tube with corner film flow using CFD and LBM methods, respectively.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Pore Network Modeling of Imbibition in Real Porous Media with Corner Film Flow

Zhao,

Zhang,

et al. 2024

Langmuir

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Wetting films can develop in the corners of pore structures during imbibition in a strongly wetting porous medium, which may significantly influence the two-phase flow dynamics. Due to the large difference in scales between main meniscus and corner film, accurate and efficient modeling of the dynamics of corner film remains elusive. In this work, we develop a novel twopressure dynamic pore network model incorporating the interacting capillary bundle model to analyze the competition between the main meniscus and corner film flow in real porous media. A pore network with four-point star-shaped pore bodies and throat bonds is extracted from the real porous medium based on the pore shape factor and pore cross-sectional area, which is then decomposed into several layers of sub-pore networks, where the first layer of sub-pore network simulates the main meniscus flow while the upper layers characterize the corner film flow. The two-phase flow conductance of throat bonds for different layers of sub-pore networks are determined by high-resolution two-phase lattice Boltzmann modeling, thus inherently considering the viscous coupling effect. In addition, two artificial neural network models are developed to predict the two phases' flow conductance based on the shape of the throat cross section and the fluid properties. The accuracy of the developed model is validated with a lattice Boltzmann simulation of imbibition in a strongly wetting square tube. Then the model is used to simulate imbibition in a strongly wetting sandstone porous medium, and the competition between the main meniscus and the corner film flow is analyzed. The results show that with decreasing capillary number and viscosity ratio between wetting and nonwetting fluids, the development of the wetting corner film becomes more significant.

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Lattice Boltzmann modelling of colloidal suspensions drying in porous media accounting for local nanoparticle effects

Cited by 15 publications

References 75 publications

Recent Progress in Heat and Mass Transfer Modeling for Chemical Vapor Deposition Processes

Recent Progress in Heat and Mass Transfer Modeling for Chemical Vapor Deposition Processes

An Overview of Micro- and Nano-Dispersion Additives for Asphalt and Bitumen for Road Construction

Dynamic Pore Network Modeling of Imbibition in Real Porous Media with Corner Film Flow

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