Microfluidic colloid filtration

Linkhorst, John; Beckmann, Torsten; Go, Dennis; Kuehne, Alexander J. C.; Weßling, Matthias

doi:10.1038/srep22376

Cited by 63 publications

(54 citation statements)

References 18 publications

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“…Clogging is encountered at many length scales, ranging from the deposition of marginally-soluble asphaltenes at pipe walls in oil recovery1, the formation of protein fouling layers in waste water treatment23, particle clogging during membrane filtration4 or microfluidic operations567. Similar phenomena are encountered at much larger length scales such as in blockades of granular hopper flows8, the emergence of traffic jams on merging lanes910 or in crowds swarming through narrow escape routes1112.…”

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confidence: 99%

Transition-state theory predicts clogging at the microscale

Laar

Klooster

Schroën

et al. 2016

Sci Rep

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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.

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confidence: 99%

Transition-state theory predicts clogging at the microscale

Laar

Klooster

Schroën

et al. 2016

Sci Rep

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“…Fouling by colloidal particles remains a major issue in many industrial processes including particle synthesis and solid handling in microreactors, membrane filtration, and liquid chromatography, often leading to complete stoppage of the process [1]. Even though this clogging issue is specific to each application, some generic features have been identified thanks to the use of microfluidic technology coupled with various imaging techniques such as confocal microscopy [2][3][4][5][6][7]. This technology enables the design of microdevices with complex geometries [8] that mimic industrial processes, in particular membrane filtration, and inside these devices we can follow the capture or deposition of colloidal particles over time, at the pore scale level, using diverse microscopy techniques.…”

Section: Introductionmentioning

confidence: 99%

“…Studies have determined the influence of pore geometry (width, shape, length, varying or fixed cross section) [3,5,[9][10][11], the confinement, i.e. the ratio between the particle radii and the smallest dimension of the pore [4,5,10], the polydispersity of the colloidal suspensions [12,13], the stability of the suspension with respect to the DLVO interaction potentials, between particles and the pore walls and between particles themselves [3][4][5][14][15][16], and the deformability of the particles [6].…”

Section: Introductionmentioning

confidence: 99%

“…Despite these efforts to visualize the fouling process inside model membranes, the dynamics inside a pore at the particle level remain completely unexplored. Almost all the work that has used either microfluidic setups or various kinds of membranes or microsieves onlyfocus on pores that are already partially or completely clogged, thereby ignoring the particle deposition history [3,6,[17][18][19][20].…”

Section: Introductionmentioning

confidence: 99%

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Dynamics of pore fouling by colloidal particles at the particle level

Dersoir

Schofield

Vincent

et al. 2019

Journal of Membrane Science

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Particle filtration occurs whenever particles flow through porous media such as membrane. Progressive capture or deposition of particles inside porous structure often leads to complete, and generally unwanted, fouling of the pores. Previously there has been no experimental work that has determined the particle dynamics of such a process at the pore level, since imaging the particles individually within the pores remains a challenge. Here, we overcome this issue by flowing fluorescently dyed particles through a model membrane, a microfluidic filter, imaged by a confocal microscope. This setup allows us to determine the temporal evolution of pore fouling at the particle level, from the first captured particle up to complete blocking of the pore. We show that from the very beginning of pore fouling the immobile particles inside the pore significantly participate in the capture of other flowing particles. For the first time it is determined how particles deposit inside the pore and form aggregates that eventually merge and block the pore.

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“…Thus, concentration polarization becomes a serious drawback in microfluidic membrane filtration. As in conventional macroscale filtration, membrane fouling is also a factor to be considered when designing a microfluidic filtration system [33][34][35]. In previous studies [36,37], it was demonstrated that, with a micromixer incorporated with a microfluidic membrane filtration system, the permeate flux could be significantly improved via chaotic mixing that reduces the amount of fouling on membrane surfaces.…”

Section: Introductionmentioning

confidence: 99%

Design Optimization for a Microfluidic Crossflow Filtration System Incorporating a Micromixer

et al. 2019

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In this study, we report on a numerical study on design optimization for a microfluidic crossflow filtration system incorporated with the staggered herringbone micromixer (SHM). Computational fluid dynamics (CFD) and the Taguchi method were employed to find out an optimal set of design parameters, mitigating fouling in the filtration system. The flow and the mass transfer characteristics in a reference SHM model and a plain rectangular microchannel were numerically investigated in detail. Downwelling flows in the SHM model lead to backtransport of foulants from the permeable wall, which slows down the development of the concentration boundary layer in the filtration system. Four design parameters -the number of grooves, the groove depth, the interspace between two neighboring grooves, and the interspace between half mixing periodswere chosen to construct a set of numerical experiments using an orthogonal array L 9 (3 4 ) from the Taguchi method. The Analysis of Variance (ANOVA) using the evaluated signal-to-noise (SN) ratios enabled us to identify the contribution of each design parameter on the performance. The proposed optimal SHM model indeed showed the lowest growth rate of the wall concentration compared to other SHM models.

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Microfluidic colloid filtration

Cited by 63 publications

References 18 publications

Transition-state theory predicts clogging at the microscale

Transition-state theory predicts clogging at the microscale

Dynamics of pore fouling by colloidal particles at the particle level

Design Optimization for a Microfluidic Crossflow Filtration System Incorporating a Micromixer

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