Liquid behavior inside a reflective display pixel based on electrowetting

Roques-Carmes, Thibault; Hayes, Robert A.; Feenstra, B. J.; Schlangen, Luc J. M.

doi:10.1063/1.1667595

Cited by 124 publications

(83 citation statements)

References 23 publications

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“…As discussed in section 4.1, contact angle gradients can be used to drive droplets with speeds on the order of 3-25 cm/s, and also be used to split (Figure 6 f -h), merge, or mix droplets with very low power consumption (Cho et al 2003, Pollack et al 2000. The rapid change in droplet shapes induced by electrowetting has been utilized for tunable optical lenses (Berge & Peseux 2000), switchable mirrors (Lea 1986), and optical displays (Roques-Carmes et al 2004). Electrowetting in combination 440 DARHUBER TROIAN with superhydrophobic surfaces allows for even greater variability in contact angle (Krupenkin et al 2004).…”

Section: Electrowetting On Dielectric Substratesmentioning

confidence: 99%

Principles of Microfluidic Actuation by Modulation of Surface Stresses

Darhuber

Troian

2005

Annu. Rev. Fluid Mech.

435

340

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Development and optimization of multifunctional devices for fluidic manipulation of films, drops, and bubbles require detailed understanding of interfacial phenomena and microhydrodynamic flows. Systems are distinguished by a large surface to volume ratio and flow at small Reynolds, capillary, and Bond numbers are strongly influenced by boundary effects and therefore amenable to control by a variety of surface treatments and surface forces. We review the principles underlying common techniques for actuation of droplets and films on homogeneous, chemically patterned, and topologically textured surfaces by modulation of normal or shear stresses.

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Section: Electrowetting On Dielectric Substratesmentioning

confidence: 99%

Principles of Microfluidic Actuation by Modulation of Surface Stresses

Darhuber

Troian

2005

Annu. Rev. Fluid Mech.

435

340

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“…This level set function is used to define the domain of the droplet at each instant of time, allowing the pressure and velocity fields to be computed from finite difference approximations to (13), (14), (15), (16), (17). We combine these methods in a third order Runge-Kutta time-stepping algorithm which specifies an order to the computation of the pressure field, velocity field, and level set update (see Fig.…”

Section: Numerical Implementationmentioning

confidence: 99%

“…3) Update Velocity Field: The fluid velocity components, , obey two first order time differential equations given by (16) and (17). The pressure gradient provides a forcing term in the equations, which causes a velocity field to develop.…”

Section: ) Update Level Setmentioning

confidence: 99%

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Modeling the Fluid Dynamics of Electrowetting on Dielectric (EWOD)

Walker

Shapiro

2006

J. Microelectromech. Syst.

137

118

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Abstract-This paper discusses the modeling and simulation of a parallel-plate Electrowetting On Dielectric (EWOD) device that moves fluid droplets through surface tension effects. We model the fluid dynamics by using Hele-Shaw type equations with a focus on including the relevant boundary phenomena. Specifically, we show that contact angle saturation and hysteresis are needed to predict the correct shape and time scale of droplet motion. We demonstrate this by comparing our simulation to experimental data for a splitting droplet. Without these boundary effects, the simulation shows the droplet splitting into three pieces instead of two and the motion is over 15 times faster than the experiment. We then show how including the saturation characteristics of the device, and a simple model of contact angle hysteresis, allows the simulation to better predict the splitting experiment. The match is not perfect and suffers mainly because contact line pinning is not included. This is followed by a comparison between our simulation, whose parameters are now frozen, and a new experiment involving bulk droplet motion. Our numerical implementation uses the level set method, is fast, and is being used to design algorithms for the precise control of microdroplet motion, mixing, and splitting.[1439]

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“…Thus, the droplet can move, split, and merge in a controlled fashion. Several applications use EWOD as a main driving force: mass spectrometry [44,25], 'lab-on-a-chip' [33,18,20,32], particle separation/concentration control [10,41], auto-focus cell phone lenses [5], and colored oil pixels for laptops and video-speed smart paper [19,30,31].…”

Section: Introductionmentioning

confidence: 99%

A Mixed Finite Element Method for EWOD That Directly Computes the Position of the Moving Interface

Falk¹,

Walker²

2013

SIAM J. Numer. Anal.

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Abstract. A new mixed finite element method is proposed and analyzed for simulating two-phase droplet motion in a micro-scale device driven by Electrowetting-On-Dielectric (EWOD). The new feature of the method is that the finite element scheme is based on a weak formulation of the problem which includes the position of the moving interface and the curvature of its boundary as basic unknowns to be determined along with the velocity field and pressure. Well-posedness of the semi-discrete and fully discrete formulations and error estimates with minimal regularity assumptions are proved. Numerical examples are given to illustrate the robustness of the method.

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Liquid behavior inside a reflective display pixel based on electrowetting

Cited by 124 publications

References 23 publications

Principles of Microfluidic Actuation by Modulation of Surface Stresses

Principles of Microfluidic Actuation by Modulation of Surface Stresses

Modeling the Fluid Dynamics of Electrowetting on Dielectric (EWOD)

A Mixed Finite Element Method for EWOD That Directly Computes the Position of the Moving Interface

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