Electric Control of Droplets in Microfluidic Devices

Link, Darren R.; Grasland-Mongrain, Erwan; Duri, Agnes; Sarrazin, Flavie; Cheng, Zhengdong; Cristobal, Galder; Márquez, Manuel; Weitz, David A.

doi:10.1002/anie.200503540

Cited by 641 publications

(521 citation statements)

References 31 publications

(23 reference statements)

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“…For example, charged water droplets dispersed in an oil phase can be addressed by means of DC electric field into specific parts of a microfluidic structure. 8 The droplets can be used as containers for chemical and biological molecules or cells. 9 For example, precise control of droplet motion/manipulation via external electric fields has been employed in works.…”

Section: Introductionmentioning

confidence: 99%

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Oscillatory motion of water droplets in kerosene above co-planar electrodes in microfluidic chips

et al. 2014

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We experimentally observed oscillatory motion of water droplets in microfluidic systems with coplanar microelectrodes under imposed DC electric fields. Two-electrode arrangement with no bipolar electrode and eight-electrode arrangement with six bipolar microelectrodes were investigated. Kerosene was used as the continuous phase. We studied the dependences of the oscillation frequency on the electric field intensity and ionic strength of the water phase. We found that the electric field dependence is strongly nonlinear and discussed possible reasons of this phenomenon, e.g., the droplet deformation at electrode edges that affects the charge transfer between the electrode and droplet or the interplay between the Coulomb force on free charge and the dielectrophoretic force. Our experiments further revealed that the oscillation frequency decreases with growing salt concentration in the two-electrode arrangement, but increases in the eight-electrode arrangement, which was attributed to surface tension related processes and electrochemical processes on the bipolar electrodes. Finally, we analyzed the effects of the electric field on the oscillatory motion by means of a simplified mathematical model. It was shown that the electric force imposed on the droplet charge is the key factor to induce the oscillations and the dielectrophoretic force significantly contributes to the momentum transfer at the electrode edges. For the same electric field strength, the model is able to predict the same oscillation frequency as that observed in the experiments.

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Section: Introductionmentioning

confidence: 99%

“…: +420 2 2044 3168, Fax: +420 2 2044 4320. Fundamental work on an advanced manipulation of leaky dielectric droplets (water electrolytes) dispersed in a dielectric fluid (nonconductive oil) was published by Link et al in 2006. 8 A pair of microelectrodes was used to electrically charge water droplets.…”

Section: Introductionmentioning

confidence: 99%

Oscillatory motion of water droplets in kerosene above co-planar electrodes in microfluidic chips

et al. 2014

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“…8,9 Additionally, surfactants are often used to stabilize droplets, hindering coalescence. 6,10 In microfluidics, flow-induced coalescence in droplet streams has been demonstrated in long slowly diverging channels.…”

Section: Introductionmentioning

confidence: 99%

“…Active control of droplet coalescence in microfluidics has been achieved using electric fields to bring together oppositely charged droplets in T-junctions 8 and straight channels. 9,13,14 Magnetic fields have also been used with success.…”

Section: Introductionmentioning

confidence: 99%

Coalescence and splitting of confined droplets at microfluidic junctions

et al. 2009

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The ability to merge two droplets is an important component of droplet-based lab-on-a-chip devices, yet flow-induced coalescence is difficult to achieve due to long film drainage times compared with relatively short residence times. We examine droplet collisions at a simple microfluidic T-junction and characterize the response for a wide range of droplet sizes and speeds. We find that three primary responses occur, where coalescence occurs easily at low collision speeds, smaller droplets traveling faster slip past one another without coalescing, and larger and faster droplets can break one another into multiple segments. The critical capillary number for coalescence agrees well with previously reported scaling for isolated droplet pairs when local curvature and speed are taken into account. The critical capillary number for splitting of droplets agrees well with a previously reported stability condition for individual droplets stretching in an extensional flow. Quantifying the necessary conditions for coalescence and non-coalescence behavior should enable the informed design of lab on chip devices based on discrete liquid segments.

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“…Spontaneous and combinatorial pairing of droplets requires precise synchronization of approaching droplets in time and space by adjusting the droplet interval. However, in order to prevent irregularities in the spacing control of droplets, it is required to integrate with additional microfluidic components such as electrode for applying electric field 12,13 or multi-layered chambers 14 and valves 15 for temporal stopping droplets. These integration issues have limitations in further incorporation of other microfluidic components for extra droplet manipulation.…”

Section: Introductionmentioning

confidence: 99%

Microbridge structures for uniform interval control of flowing droplets in microfluidic networks

Lee

et al. 2011

Biomicrofluidics

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Precise temporal control of microfluidic droplets such as synchronization and combinatorial pairing of droplets is required to achieve a variety range of chemical and biochemical reactions inside microfluidic networks. Here, we present a facile and robust microfluidic platform enabling uniform interval control of flowing droplets for the precise temporal synchronization and pairing of picoliter droplets with a reagent. By incorporating microbridge structures interconnecting the dropletcarrying channel and the flow control channel, a fluidic pressure drop was derived between the two fluidic channels via the microbridge structures, reordering flowing droplets with a defined uniform interval. Through the adjustment of the control oil flow rate, the droplet intervals were flexibly and precisely adjustable. With this mechanism of droplet spacing, the gelation of the alginate droplets as well as control of the droplet interval was simultaneously achieved by additional control oil flow including calcified oleic acid. In addition, by parallel linking identical microfluidic modules with distinct sample inlet, controlled synchronization and pairing of two distinct droplets were demonstrated. This method is applicable to facilitate and develop many droplet-based microfluidic applications, including biological assay, combinatorial synthesis, and high-throughput screening.

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Electric Control of Droplets in Microfluidic Devices

Cited by 641 publications

References 31 publications

Oscillatory motion of water droplets in kerosene above co-planar electrodes in microfluidic chips

Oscillatory motion of water droplets in kerosene above co-planar electrodes in microfluidic chips

Coalescence and splitting of confined droplets at microfluidic junctions

Microbridge structures for uniform interval control of flowing droplets in microfluidic networks

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