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Journal ArticleDOI

Microstructure of the near-wall layer of filtration-induced colloidal assembly.

Mohand Larbi Mokrane1, Térence Desclaux1, Jeffrey F. Morris2, Pierre Joseph1, Olivier Liot1 
University of Toulouse1, City College of New York2
04 Nov 2020-Soft Matter (The Royal Society of Chemistry)-Vol. 16, Iss: 42, pp 9726-9737
TL;DR: An experimental study of filtration of a colloidal suspension using microfluidic devices involving colloid-colloid repulsive interactions and fluid velocity, which shows some heterogeneity in the near-wall layer microstructure.
Abstract: This paper describes an experimental study of filtration of a colloidal suspension using microfluidic devices. A suspension of micrometer-scale colloids flows through parallel slit-shaped pores at fixed pressure drop. Clogs and cakes are systematically observed at pore entrance, for variable applied pressure drop and ionic strength. Based on image analysis of the layer of colloids close to the device wall, global and local studies are performed to analyse in detail the near-wall layer microstructure. Whereas global porosity of this layer does not seem to be affected by ionic strength and applied pressure drop, a local study shows some heterogeneity: clogs are more porous at the vicinity of the pore than far away. An analysis of medium-range order using radial distribution function shows a slightly more organized state at high ionic strength. This is confirmed by a local analysis using two-dimension continuous wavelet decomposition: the typical size of crystals of colloids is larger for low ionic strength, and it increases with distance from the pores. We bring these results together in a phase diagram involving colloid–colloid repulsive interactions and fluid velocity.

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This is an author’s version published in: https://oatao.univ-toulouse.fr/2 74 62
To cite this version:
Mokrane, Mohand Larbi and Desclaux, Térence and Moris, Jeffrey F. and Joseph,
Pierre and Liot, Olivier
Microstructure of the near-wall layer of filtration-induced
colloidal assembly. (2020) Soft Matter, 16 (42). 9726-9737. ISSN 1744-683X .
Official URL:
https://doi.org/10.1039/D0SM01143F
Open Archive Toulouse Archive Ouverte
Citations
More filters
Journal ArticleDOI
Membrane Fouling Phenomena in Microfluidic Systems: From Technical Challenges to Scientific Opportunities.

[...]

Andrea Iginio Cirillo1, Giovanna Tomaiuolo1, Stefano Guido1
University of Naples Federico II1
13 Jul 2021-Micromachines
TL;DR: In this article, the authors explore fouling through microfluidic systems, assessing the fundamental interactions involved and how micro-fluidics enables the comprehension of the mechanisms characterizing the process.
Abstract: The almost ubiquitous, though undesired, deposition and accumulation of suspended/dissolved matter on solid surfaces, known as fouling, represents a crucial issue strongly affecting the efficiency and sustainability of micro-scale reactors. Fouling becomes even more detrimental for all the applications that require the use of membrane separation units. As a matter of fact, membrane technology is a key route towards process intensification, having the potential to replace conventional separation procedures, with significant energy savings and reduced environmental impact, in a broad range of applications, from water purification to food and pharmaceutical industries. Despite all the research efforts so far, fouling still represents an unsolved problem. The complex interplay of physical and chemical mechanisms governing its evolution is indeed yet to be fully unraveled and the role played by foulants' properties or operating conditions is an area of active research where microfluidics can play a fundamental role. The aim of this review is to explore fouling through microfluidic systems, assessing the fundamental interactions involved and how microfluidics enables the comprehension of the mechanisms characterizing the process. The main mathematical models describing the fouling stages will also be reviewed and their limitations discussed. Finally, the principal dynamic investigation techniques in which microfluidics represents a key tool will be discussed, analyzing their employment to study fouling.

8 citations

Journal ArticleDOI
Influence of the solid fraction on the clogging by bridging of suspensions in constricted channels.

[...]

N. U. Vani, Sacha Escudier, Alban Sauret
24 Aug 2022-Soft Matter
TL;DR: In this article , the formation of a stable arch of particles at a constriction that hinders the transport of particles downstream of the clog was studied. But the authors focused on the role of the volume fraction of the suspension on the clogging dynamics.
Abstract: Clogging can occur whenever a suspension of particles flows through a confined system. The formation of clogs is often correlated to a reduction in the cross-section of the channel. In this study, we consider the clogging by bridging, i.e., through the formation of a stable arch of particles at a constriction that hinders the transport of particles downstream of the clog. To characterize the role of the volume fraction of the suspension on the clogging dynamics, we study the flow of particulate suspensions through 3D-printed millifluidic devices. We systematically characterize the bridging of non-Brownian particles in a quasi-bidimensional system in which we directly visualize and track the particles as they flow and form arches at a constriction. We report the conditions for clogging by bridging when varying the constriction width to particle diameter ratio for different concentrations of the particles in suspension. We then discuss our results using a stochastic model to rationalize the influence of solid fraction on the probability of clogging. Understanding the mechanisms and conditions of clog formation is an important step for optimizing engineering design and developing more reliable dispensing systems.

6 citations

Journal ArticleDOI
Templating the morphology of soft microgel assemblies using a nanolithographic 3D-printed membrane

[...]

John Linkhorst1, Jonas Lölsberg2, Jonas Lölsberg1, Sebastian Thill1, Johannes Lohaus1, Arne Lüken1, Gerhard Naegele3, Matthias Wessling2, Matthias Wessling1 
RWTH Aachen University1, Leibniz Association2, Forschungszentrum Jülich3
12 Jan 2021-Scientific Reports
TL;DR: In this article, the influence of the porous membrane morphology on crystal formation and compaction behavior of soft filter cakes under dead-end filtration conditions was analyzed by optical visualization and pressure data.
Abstract: Filter cake formation is the predominant phenomenon limiting the filtration performance of membrane separation processes. However, the filter cake’s behavior at the particle scale, which determines its overall cake behavior, has only recently come into the focus of scientists, leaving open questions about its formation and filtration behavior. The present study contributes to the fundamental understanding of soft filter cakes by analyzing the influence of the porous membrane’s morphology on crystal formation and the compaction behavior of soft filter cakes under filtration conditions. Microfluidic chips with nanolithographic imprinted filter templates were used to trigger the formation of crystalline colloidal filter cakes formed by soft microgels. The soft filter cakes were observed via confocal laser scanning microscopy (CLSM) under dead-end filtration conditions. Colloidal crystal formation in the cake, as well as their compaction behavior, were analyzed by optical visualization and pressure data. For the first time, we show that exposing the soft cake to a crystalline filter template promotes the formation of colloidal crystallites and that soft cakes experience gradient compression during filtration.

5 citations

Journal ArticleDOI
Structure and flow conditions through a colloidal packed bed formed under flow and confinement.

[...]

Nathalie Delouche, Benjamin Dersoir, Andrew B. Schofield, Hervé Tabuteau
17 Nov 2022-Soft Matter
TL;DR: In this paper , the relative contribution of the confinement dimensions, the ionic strength and the flow conditions on the particle volume fraction of the resultant accumulation is determined, and it is shown that in high confinement the irreversible deposition of particles on the channel surfaces controls the structure of the accumulation, and thus the flow through it, irrespective of the other conditions, leading to a Darcy flow.
Abstract: When a colloidal suspension flows in a constriction, particles deposit and are able to clog it entirely, this fouling process being followed by the accumulation of particles. The knowledge of the dynamics of formation of such a dense particle assembly behind the clog head and its structural features is of primary importance in many industrial and environmental processes and especially during filtration. While most studies concentrate on the conditions under which pore clogging occurs, i.e., the pore narrowing up to its complete obstruction, this paper focuses on the accumulation of particles that follows pore obstruction. We determine the relative contribution of the confinement dimensions, the ionic strength and the flow conditions on the permeability and particle volume fraction of the resultant accumulation. In high confinement the irreversible deposition of particles on the channel surfaces controls the structure of the accumulation and the flow through it, irrespective of the other conditions, leading to a Darcy flow. Finally, we show that contrarily to the clog head, in which there is cohesion between particles, those in the subsequent accumulation are held together by the fluid and form a dense suspension of repulsive hard spheres.
References
More filters
Journal ArticleDOI
Direct force measurements between carboxylate-modified latex microspheres and glass using atomic force microscopy

[...]

Shoeleh Assemi1, Jakub Nalaskowski1, William P. Johnson1
University of Utah1
01 Sep 2006-Colloids and Surfaces A: Physicochemical and Engineering Aspects
TL;DR: In this paper, the authors used the depths of the primary minima of the theoretical DLVO curves fitted to AFM approach curves, were used to estimate adhesion forces according to previously published approaches, and were compared to the pulloff forces measured by AFM.

45 citations

Journal ArticleDOI
Growth of clogs in parallel microchannels

[...]

Alban Sauret1, Alban Sauret2, Katarzyna Somszor, Emmanuel Villermaux3, Emmanuel Villermaux4, Emmanuel Villermaux5, Emilie Dressaire6, Emilie Dressaire1 
University of California, Santa Barbara1, Saint-Gobain2, Institut Universitaire de France3, Aix-Marseille University4, Massachusetts Institute of Technology5, Université Paris-Saclay6
01 Oct 2018
TL;DR: Sauret et al. as discussed by the authors presented a model that predicts the growth of the aggregate formed upon clogging of a microchannel, which leads to a dramatic reduction of the flow rate.
Abstract: Author(s): Sauret, Alban; Somszor, Katarzyna; Villermaux, Emmanuel; Dressaire, Emilie | Abstract: During the transport of colloidal suspensions in microchannels, the deposition of particles can lead to the formation of clogs, typically at constrictions. Once a clog is formed in a microchannel, advected particles form an aggregate upstream from the site of the blockage. This aggregate grows over time, which leads to a dramatic reduction of the flow rate. In this paper, we present a model that predicts the growth of the aggregate formed upon clogging of a microchannel. We develop an analytical description that captures the time evolution of the volume of the aggregate, as confirmed by experiments performed using a pressure-driven suspension flow in a microfluidic device. We show that the growth of the aggregate increases the hydraulic resistance in the channel and leads to a drop in the flow rate of the suspensions. We then derive a model for the growth of aggregates in multiple parallel microchannels where the clogging events are described using a stochastic approach. The aggregate growths in the different channels are coupled. Our work illustrates the critical influence of clogging events on the evolution of the flow rate in microchannels. The coupled dynamics of the aggregates described here for parallel channels is key to bridge clogging at the pore scale with macroscopic observations of the flow rate evolution at the filter scale.

41 citations

Journal ArticleDOI
Transition-state theory predicts clogging at the microscale

[...]

T. van de Laar1, S. ten Klooster1, Karin Schroën1, Joris Sprakel1
Wageningen University and Research Centre1
22 Jun 2016-Scientific Reports
TL;DR: A microfluidic model combined with quantitative real-time imaging is used to explore the influence of pore geometry and particle interactions on suspension clogging in constrictions and finds a distinct dependence of the clogging rate on the entrance angle to a membrane pore.
Abstract: Clogging is one of the main failure mechanisms encountered in industrial processes such as membrane filtration. Our understanding of the factors that govern the build-up of fouling layers and the emergence of clogs is largely incomplete, so that prevention of clogging remains an immense and costly challenge. In this paper we use a microfluidic model combined with quantitative real-time imaging to explore the influence of pore geometry and particle interactions on suspension clogging in constrictions, two crucial factors which remain relatively unexplored. We find a distinct dependence of the clogging rate on the entrance angle to a membrane pore which we explain quantitatively by deriving a model, based on transition-state theory, which describes the effect of viscous forces on the rate with which particles accumulate at the channel walls. With the same model we can also predict the effect of the particle interaction potential on the clogging rate. In both cases we find excellent agreement between our experimental data and theory. A better understanding of these clogging mechanisms and the influence of design parameters could form a stepping stone to delay or prevent clogging by rational membrane design.

38 citations

Journal ArticleDOI
Yield of reversible colloidal gels during flow start-up: release from kinetic arrest.

[...]

Lilian Johnson1, Lilian Johnson2, Benjamin J. Landrum2, Roseanna N. Zia1
Stanford University1, Cornell University2
20 Jun 2018-Soft Matter
TL;DR: In this paper, the authors study yield of reversible colloidal gels during start-up of shear flow via dynamic simulation, connecting rheological yield to detailed measurements of structure, bond dynamics, and potential energy.
Abstract: Yield of colloidal gels during start-up of shear flow is characterized by an overshoot in shear stress that accompanies changes in network structure. Prior studies of yield of reversible colloidal gels undergoing strong flow model the overshoot as the point at which network rupture permits fluidization. However, yield under weak flow, which is of interest in many biological and industrial fluids shows no such disintegration. The mechanics of reversible gels are influenced by bond strength and durability, where ongoing rupture and re-formation impart aging that deepens kinetic arrest [Zia et al., J. Rheol., 2014, 58, 1121], suggesting that yield be viewed as release from kinetic arrest. To explore this idea, we study reversible colloidal gels during start-up of shear flow via dynamic simulation, connecting rheological yield to detailed measurements of structure, bond dynamics, and potential energy. We find that pre-yield stress grows temporally with the changing roles of microscopic transport processes: early time behavior is set by Brownian diffusion; later, advective displacements permit relative particle motion that stretches bonds and stores energy. Stress accumulates in stretched, oriented bonds until yield, which is a tipping point to energy release, and is passed with a fully intact network, where the loss of very few bonds enables relaxation of many, easing glassy arrest. This is immediately followed by a reversal to growth in potential energy during bulk plastic deformation and condensation into larger particle domains, supporting the view that yield is an activated release from kinetic arrest. The continued condensation of dense domains and shrinkage of network surfaces, along with a decrease in the potential energy, permit the gel to evolve toward more complete phase separation, supporting our view that yield of weakly sheared gels is a 'non-equilibrium phase transition'. Our findings may be particularly useful for industrial or other coatings, where weak, slow application via shear may lead to phase separation, inhibiting smooth distribution.

36 citations

Journal ArticleDOI
Self-Limited Accumulation of Colloids in Porous Media.

[...]

Gaétan Gerber1, Gaétan Gerber2, M. Bensouda1, David A. Weitz2, Philippe Coussot1 
University of Paris1, Harvard University2
10 Oct 2019-Physical Review Letters
TL;DR: The complete deposition dynamics are derived and it is shown that colloid accumulation is a self-limited mechanism towards a deposited fraction associated with a balance between the particle interactions and the imposed flow rate.
Abstract: We present local direct imaging of the progressive adsorption of colloidal particles inside a 3D model porous medium. By varying the interparticle electrostatic interactions, we observe a large range of particle deposition regimes, from a single layer of particles at the surface of the medium to multiple layers and eventually clogging of the system. We derive the complete deposition dynamics and show that colloid accumulation is a self-limited mechanism towards a deposited fraction associated with a balance between the particle interactions and the imposed flow rate. These trends are explained and predicted using a simple probability model considering the particle adsorption energy and the variation of the drag energy with evolving porosity. This constitutes a direct validation of speculated particle transport mechanisms, and a further understanding of accumulation mechanisms.

33 citations

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