A scaling model for electrowetting-on-dielectric microfluidic actuators

Song, J. H.; Evans, R.D.; Lin, Yan; Hsu, Bang-Ning; Fair, Richard B.

doi:10.1007/s10404-008-0360-y

Cited by 133 publications

(82 citation statements)

References 37 publications

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“…1) with equal thickness, h, which are hydrophobic such that R V ¼ h/2 and have a value of h such that R V ooR h , the Laplace pressure for the ink in both the upper and lower channel can be approximated as DP ¼ 2g/h. To achieve movement, electromechanical pressure locally reduces the pressure as predicted 4 by DP ¼ À CV 2 /h, where C is the capacitance of the hydrophobic dielectric and V is the voltage applied to the electrode towards which the ink will move 5,9 . The minimum V for movement can be very low, but practically ranges from 5 to 30 V depending on C and/or the required switching speed.…”

Section: Resultsmentioning

confidence: 99%

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Bright e-Paper by transport of ink through a white electrofluidic imaging film

et al. 2012

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Many of the highest performance approaches for electronic paper use voltage to reveal or hide dark pigments or dyes over a white pixel surface, and the reflectance of white pixels is lower than in real paper because the dark pigments or dyes can never be fully removed from the visible pixel area. Here, we introduce a re-designed approach for electronic paper that transposes coloured ink in front of or behind a white microfluidic film. Pixels can provide 490% reflective area and have demonstrated o15 ms switching for 150 pixels-per-inch resolution. This new approach is also the first of its kind for electrowetting-style displays by allowing non-aligned lamination fabrication, and is the first ever colourant-transposing pixel that eliminates the need for ink microencapsulation or pixel borders.

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Section: Resultsmentioning

confidence: 99%

“…Figure 4 shows a 150 PPI device switching a 200-mm electrode line. An added advantage of scaling to smaller dimensions is that it leads to a decrease in switching time 9 . Accordingly, both 25 and 150 PPI device switching profiles are plotted in Fig.…”

Section: Resultsmentioning

confidence: 99%

Bright e-Paper by transport of ink through a white electrofluidic imaging film

et al. 2012

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“…This section uses the electromechanical framework developed by Kumari et al [12] to highlight the physics underlying each of the three actuation regimes; similar considerations have been employed by Jones [44] and Chatterjee et al [45] to study frequency-dependent electrical actuation. The framework by Kumari et al [12] is used to develop a scaling analysis-based model to compare the actuation force in each of the three regimes.…”

Section: Electromechanical Modeling Of the Electrical Actuation Forcementioning

confidence: 99%

“…The presence of a surrounding filler fluid leads to an additional viscous drag on the droplet (typically EW actuation is carried out in air or in an oil environment). This viscous drag has also been modeled semi-empirically [26,44,52]. While the presence of an oil carrier medium increases the viscous drag, the contact line friction and the threshold voltage for EW-actuation is reduced in the presence of an oil environment.…”

Section: Modeling Droplet Motionmentioning

confidence: 99%

“…Owing to the complexities of modeling the different phenomena influencing droplet motion, simplified analyses have been conveniently employed to model droplet motion [23,26,27,44,50,54]. As an illustration, Bahadur and Garimella [26] modeled EW-induced transient droplet motion by representing the opposing forces using simplified algebraic expressions and incorporated them in the overall force balance model for a droplet which led to: (13) where m is the droplet mass, F act is the electrical actuation force, F w is the force resulting from wall stress, F f is the filler fluid drag, and F cl is the contact line friction.…”

Section: Modeling Droplet Motionmentioning

confidence: 99%

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Electrical actuation-induced droplet transport on smooth and superhydrophobic surfaces

Bahadur¹,

Garimella

2010

International Journal of Micro-Nano Scale Transport

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E El le ec ct tr ri ic ca al l a ac ct tu ua at ti io on n--i in nd du uc ce ed d d dr ro op pl le et t t tr ra an ns sp po or rt t o on n s sm mo oo ot th h a an nd AbstractElectrical control of liquid droplet motion and wettability has wide-ranging applications in the field of MEMS, lab-on-a-chip devices and surface engineering, in view of the resulting enhanced flow control opportunities, low power consumption and the absence of mechanical moving parts. This article summarizes recent progress towards understanding of the fundamentals underlying electrical actuation of droplets on smooth and superhydrophobic surfaces. Electrical actuation of liquid droplets with widely differing electrical properties on smooth surfaces is first discussed. Electromechanical considerations are employed to study the actuation force on a generic liquid droplet across the entire spectrum of electrical actuation regimes. The challenges in understanding the fluid flow and dissipation mechanisms associated with a discrete moving droplet are discussed. The role of electrical voltages, interfacial energies and surface morphology in determining droplet states (nonwetting Cassie state and wetting Wenzel state) and triggering state transitions on superhydrophobic surfaces is then mapped out. Critical phenomena associated with droplet transitions on superhydrophobic surfaces (energy barrier for the Cassie-Wenzel transition, lack of spontaneous reversibility of the Cassie-Wenzel transition, robustness of the Cassie state, and the role of the roughness elements) are analyzed. The article also highlights key avenues for future research in the fields of electrical actuation-based microfluidics and superhydrophobic surfaces. INTRODUCTIONElectrical actuation of liquid droplet motion on smooth and superhydrophobic surfaces has been studied as a tool for controlling microfluidic operations which determine the performance of lab-on-a-chip devices, optical systems, fluidic displays and other MEMS-based fluidic devices. Key advantages of electrical actuation of liquids (in the form of discrete droplets) over mechanical actuation include the absence of moving mechanical parts, opportunities for enhanced and reconfigurable flow control, compatibility with liquids of widely different electrical properties, compatibility with existing fabrication techniques, and ease of integration with a chip-based microfluidic platform. Electrical actuation techniques are also very energy-efficient, typically requiring only microwatts of power per microfluidic operation. Owing to these advantages, electrical actuation-based control has attracted significantly more research interest than competing non-mechanical liquid control technologies such as thermocapillarity [1] (reduction of surface tension by temperature, leading to fluid motion), optoelectrowetting [2] (light-controlled surface tension induced pumping) and vapor bubble-based pumping [3]. Electrical actuation of liquid droplets on smooth surfaces and its potential applications have been reviewed by Mugele and Ba...

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Fundamentals of Applied Electrowetting

2018

Electrowetting

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A scaling model for electrowetting-on-dielectric microfluidic actuators

Cited by 133 publications

References 37 publications

Bright e-Paper by transport of ink through a white electrofluidic imaging film

Bright e-Paper by transport of ink through a white electrofluidic imaging film

Electrical actuation-induced droplet transport on smooth and superhydrophobic surfaces

Fundamentals of Applied Electrowetting

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