Towards a continuous microfluidic rheometer

Guillot, Pierre; Moulin, Thomas; Kötitz, R.; Guirardel, Matthieu; Dodge, Arash; Joanicot, Mathieu; Colin, Annie; Bruneau, Charles‐Henri; Colin, Thierry

doi:10.1007/s10404-008-0273-9

Cited by 39 publications

(21 citation statements)

References 27 publications

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“…It was not absolute flow rates but the phase ratio determining the interface location in a certain microchannel, as shown in Fig. 3, which is accordant with the conclusion drawn by Guillot et al (2008). In Fig.…”

Section: Conditions For Plf Formingsupporting

confidence: 92%

Phase separation of parallel laminar flow for aqueous two phase systems in branched microchannel

Lü

Xia

Luo

2010

Microfluid Nanofluid

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Aqueous two phase systems (ATPSs) have good biocompatibility and special selectivity. Their phase equilibrium and applications in biological analysis have received much attention. Herein, parallel laminar flow (PLF) in the microchannel can provide an effective platform to enhance mass transfer and preserve separate phases simultaneously. As fundamentals in feasible and convenient sampling of PLF for ATPS, the phase separation methods and rules in branched microchannel were studied in this work, selecting PEG 4000 ? Na 2 SO 4 ? H 2 O as a model system. The exploration of flow pattern showed that a stable PFL was easily to form in the shallow microchannel of 200 lm (depth) 9 600 lm (width), as long as the velocity of lower phase was higher than 0.51 mm/s. The phase interface of PLF could be easily controlled by the flow ratio of two phases. Single-phase separation could be reliably achieved in T-junction outlets when the flow rate of outlet ascertains to be smaller or larger than that of inlet on the same side. The trifurcate outlets with an extra middle channel could help realize a simultaneous two-phase separation. The flow rate of the extra channel is the key for the phase separation performance, the range of which available for simultaneous two-phase separation is determined by the resistance balance and the flow rates deviation offsetting as well. It is favor for increasing phase separation efficiency to make the products of flow rate, viscosity, and the length of corresponding outlet channel close with each other for the upper phase and the lower phase. The adjustable lengths of three channels can provide flexible choices to enhance simultaneous two-phase separation of diversified ATPSs at various operating flow ratios. A multiport microchip with T-junction inlets and trifurcate outlets designed for adjusting the lengths of branched channels on-chip is a convenient tool for PLF contact and in situ phase separation of ATPSs in varieties of application.

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Section: Conditions For Plf Formingsupporting

confidence: 92%

Phase separation of parallel laminar flow for aqueous two phase systems in branched microchannel

Lü

Xia

Luo

2010

Microfluid Nanofluid

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“…The significantly reduced quantity of sample consumption and increased rate of heat/mass transfer and chemical reactions are the key advantages of microfluidic devices. Applications range from pH and temperature sensors to fluid actuators, such as micronozzels, micropumps (Laser and Santiago, 2004;Woias, 2005), micromixers (Hessel et al, 2005;Nguyen and Wu, 2005), microvalves (Kwong and Chong, 2006), micro-rheometers (Guillot et al, 2008), biotechnology areas such as the analysis of DNA and proteins, and biodefence (Whitsides and Stroock, 2001), as well as LOC systems for drug delivery, chemical analysis, and biomedical diagnosis (Bousse et al, 2000). A blood analyzer MEMS requires taking a sample by means of generating blood flow through a microneedle of the microfluidic system.…”

Section: Introductionmentioning

confidence: 99%

Electroviscous effects in steady fully developed flow of a power-law liquid through a cylindrical microchannel

Bharti

Harvie

Davidson

2009

International Journal of Heat and Fluid Flow

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“…Simulations at higher length scales clearly showed that particular movement. The position of the interface between two Newtonian fluids was the same with various flow rates, as long as the ratio between then remained constant, which was also noted by Guillot et al (2008).…”

Section: Discussionmentioning

confidence: 82%

“…Lu et al (2011) acknowledged parallel laminar flow for being an effective platform for enhanced mass transfer, for simultaneous preservation of separate phases, for fast phase equilibrium or diffusivity determination with trace chemical consumption, and for continuous, efficient and even multi-stage industrial extraction techniques. Münchow et al (2007) utilized parallel flow for electrophoretic partitioning of proteins and Guillot et al (2008) developed a method to perform automated rheological measurements on a microfluidic chip. They also numerically calculated the steady-state developed velocity profiles for two-phase parallel flow and Galambos and Forster (1998) used an analytical solution of simplified Navier-Stokes equations to obtain the velocity profile at steady-state and to predict the position of the interface of developed flow.…”

Section: Introductionmentioning

confidence: 99%

Parallel flow of immiscible liquids in a microreactor: modeling and experimental study

Pohar

Lakner

Plazl

2011

Microfluid Nanofluid

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Two-phase parallel flow can be utilized in microreactor engineering for performing reactions and extractions, and also for achieving efficient phase separation at the exit of the microreactor. Typical laminar flow at the microscale allows two phases to flow in parallel without mixing, allowing highly controlled conditions for a specific chemical process. Since the liquid with the higher viscosity has a tendency to occupy a larger fraction of the microchannel, the position of the interface can be controlled through the adjustment of flow rates. The prediction of the position of the interface is important for microreactor design and operation and requires the solution of the governing equations of fluid mechanics. In this work, the theoretical description for two-phase parallel flow, based on the Navier-Stokes equations in three dimensions was expressed with a mathematical model and validated with experimental observations. The movement of the interface was achieved through the adjustment of fluid properties according to the position of the central streamlines. The predicted position of the interface was in good agreement with experimental data. A correlation for the flow rate ratio required for positioning the interface in the middle of the channel for various viscosity ratios was proposed, as well as a correlation for the prediction of the parallel to slug transition for a water/n-hexane system.

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Towards a continuous microfluidic rheometer

Cited by 39 publications

References 27 publications

Phase separation of parallel laminar flow for aqueous two phase systems in branched microchannel

Phase separation of parallel laminar flow for aqueous two phase systems in branched microchannel

Electroviscous effects in steady fully developed flow of a power-law liquid through a cylindrical microchannel

Parallel flow of immiscible liquids in a microreactor: modeling and experimental study

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