Lecture 17-19 Electrowetting PDF

Summary

This lecture covers electrowetting, surface tension, and other important concepts in microfluidics. It explores the use of electrowetting as a method to manipulate droplets in microfluidic devices.

Full Transcript

Electrowetting

and

Digital Microfluidics

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Different driving forces become pertinent in microscale systems in contrast
to their macroscale counterparts to drive fluids.

Surface tension force

Important in microscale domain owing to the fact that the surface to
volume ratio increases significantly in microscale.

The control of surfaces and surface energies is one of the most important
challenges both in microtechnology in general as well as in microfluidics.
For liquid droplets of sub-millimetre dimensions, capillary forces
dominate.

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The control of interfacial energies (both liquid–vapour and solid–liquid
interfaces) has therefore become an important strategy for manipulating
droplets at surfaces.

Precise manipulation of droplets in the micrometer scale.

Four fundamental fluidic operations (creating, transporting, cutting, and
merging) with droplets are utilized to digitize droplet- based fluidic
system which has evolved into a new microfluidics paradigm

Digital Microfluidics

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 Ways to influence the interfaces

Temperature gradients

Interface motion induced by a thermal gradient between two regions of the
surface. The interface motion propagates into the bulk due to viscous forces.

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Gradients in the concentration of surfactants across droplets

Gives rise to gradients in interfacial energies, mainly at the liquid–vapour
interface, and thus produce forces that can propel droplets making use of the
thermocapillary and Marangoni effects.

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Marangoni convection occurs if the variation of the surface tension force
dominates the viscosity forces.

A dimensionless number—the Marangoni number (thermal)—determines the
strength of the convective motion

where R is the radius of the spherical cap, ρ the density of the liquid, ν the
kinematic viscosity, α the thermal diffusivity, and Δγ the variation of surface
tension on the interface.

The Marangoni number represents the ratio between the tangential stress and
the viscosity.

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 Drops Moving by Capillarity

At the microscopic scale there are other forces to move fluids that are not
efficient at the macroscopic scale. These forces are electro-osmosis and
capillarity. In particular capillarity is widely used for actuating droplets.

1. Drop Moving Over a Transition of Wettability

Resulting force directed
towards the hydrophilic Droplet at equilibrium
region

If L1 and L2 are the contact lines in the
hydrophilic and hydrophobic planes,
and θ1 and θ2 the contact angles, the
force acting on the drop is

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2. Drop Moving Uphill

Capillary forces may be sufficient to make micro-drops move upwards
on an inclined plane.
M.K. Chaudhury and G.M. Whitesides, “How to
make water run uphill,” Science, Vol. 256, pp. 1539–1541, 1992.

The required gradient in
surface free energy was
generated on a polished
silicon wafer by exposing it to
the diffusing front of a vapor
of decyltrichlorosilane,

The average velocity is
approximately 1 to 2 mm/s

A drop moves uphill towards the more hydrophilic region.

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 3. Drop Moving up a Step

A micro-drop of water is initially located on a step at the boundary
of a hydrophilic region (on top of the step) and a hydrophobic
region (at the base of the step). The drop progressively moves
towards the hydrophilic region, even if this region is located at a
higher level (simulation result)

Motion of a drop up a step towards the
hydrophilic plane (simulation)
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 4. Drop Moving Over a Gradient of Surface Concentration of Surfactant

Chemical reactions between the liquid of the droplet and the substrate can create
droplet motion. A droplet of n-alkanes containing silane molecules is placed on
a hydrophilic surface. Silane molecules form dense grafted monolayers on
silicon or glass, rendering the surface hydrophobic.

If such a droplet is deposited on a glass surface and pushed with a pipette, then
the droplet continues to move on the substrate. It moves in nearly linear
segments and changes its direction each time it encounters a hydrophobic
barrier. The droplet cannot cross its own tracks.

The advancing contact line has a hydrophilic
Young contact angle. Molecules of silane
concentrate at the vicinity of the receding
contact line and form a hydrophobic layer.
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Chemical and topographical structuring of surfaces - local
wettability

The main disadvantage of chemical and topographical patterns is
their static nature, which prevents active control of the liquids.
 Examples of the role of the interface/contact line
Evaporation of sessile droplets
It has been observed experimentally that wetting and non-wetting droplets do
not evaporate in the same way.

Water Droplet on hydrophobic (top) and hydrophilic (bottom) surfaces

In the case of a non-wetting droplet, it is the contact angle that remains
constant (CCA), the contact radius decreases gradually.

In the case of a wetting droplet the contact radius remains constant (CCR)
during the evaporation process, the contact angle decreases gradually. It is as
if the contact line was pinned on the initial contact line.
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Electrocapillarity, the basis of modern electrowetting, was first described in
detail in 1875 by Gabriel Lippmann.

the capillary depression of mercury in contact with electrolyte solutions could be
varied by applying a voltage between the mercury and electrolyte

Generic electrowetting set-up. Partially wetting liquid droplet at zero
voltage (dashed) and at high voltage (solid).

Electrowetting (EW) has proven to be very successful:

Contact angle variations of several tens of degrees are routinely
achieved.
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 Electrowetting (EW)
In EW an electrical double layer (EDL) is formed between the electrode and
aqueous solution that is between 1 nm and 10 nm thick.

Applying a voltage difference may cause a hydrophobic surface to behave like a
hydrophilic one. The electric energy counterbalances the free surface energy and
lowers the surface tension γsl.

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Switching speeds are limited (typically to several milliseconds) by the
hydrodynamic response of the droplet rather than the actual switching of the
equilibrium value of the contact angle.

Excellent stability without noticeable degradation

Nowadays, droplets can be moved along freely programmable paths on
surfaces; they can be split, merged, and mixed with a high degree of flexibility.

However, electrolysis start within a few milli-volts to make EW difficult to
use for practical applications.

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 Electrowetting-on-dielectric (EWOD)

Berge in the early 1990 introduced the idea of using a thin insulating layer to
separate the conductive liquid from the metallic electrode in order to eliminate
the problem of electrolysis - Electrowetting on dielectric (EWOD).

In EWOD there is no electric double layer, but the change in the energy
balance takes place in the hydrophobic dielectric layer; A Teflon layer, 0.8 µm
thick was used as the dielecric. Lee, J., Moon, H., Fowler, J., Schoellhammer,
T., and Kim, C.-J. (2002). Electrowetting and electrowetting-on-dielectric for
microscale liquid handling. Sens. Actuators, A, 95:259–268.

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EWOD

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 Electrowetting: basics to applications
Electrowetting has become one of the most widely used tools for manipulating
tiny amounts of liquids on surfaces.

Applications range from ‘lab-on-a-chip’ devices to adjustable lenses and new
kinds of electronic displays.

Issues

Fundamental and applied aspects.

Basic electrowetting equation,

Origin of the electrostatic forces that induce both contact angle
reduction and the motion of entire droplets.
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Issues – contd.

Limitations of the electrowetting equation

Failure of the electrowetting equation, namely the saturation of
the contact angle at high voltage,

The dynamics of electrowetting

Overview of commercial applications

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 Theoretical background
Basic aspects of wetting
In electrowetting, one is generically dealing with droplets (typical size of the
order of 1 mm or less) of partially wetting liquids (aqueous salt solutions) on
planar solid substrates.

Bond number Bo = g ∆ ρ R 2 /σ lv measures the strength of gravity with
respect to surface tension.

If Bo < 1 , the strength of gravity is neglected and the behavior of the
droplets is determined by surface tension alone.
The free energy F of a droplet is a function of the droplet shape.
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 The free energy F of a droplet is the
sum of the areas Ai of the interfaces
between the three phases, weighted by
the respective interfacial energies, i.e.
σsv, σsl , and σlv :

Force balance at the contact line F = Fif = ∑ Ai σ i − λV (1)
i

λ is equal to the pressure drop across the liquid–vapour interface.

Minimization of Eq. (l) leads to the following condition that any equilibrium liquid
morphology has to fulfill -
 1 1 
∆ P = σ lv  +  = σ lv K (2)
Laplace Equation
 r1 r 2 
relates Young’s equilibrium
σ sv − σ sl
Young Equation cos θ Y = (3) contact angle to the
σ lv interfacial energies

Both equations are approximations intended for mesoscopic scales. 21
 Electrowetting theory for homogeneous substrates

The thermodynamic and electrochemical approach - Lippmann’s derivation
- direct metal – electrolyte interfaces

Upon applying a voltage dU, an electric double layer builds up
spontaneously at the solid–liquid interface consisting of charges on the metal
surface on one hand and of a cloud of oppositely charged counter-ions on the
liquid side of the interface.

Since the accumulation is a spontaneous process, it leads to a reduction of the
(effective) interfacial tension, σeff

d σ sleff = − ρ sl d U (4)

ρ sl = ρ sl (U )is the surface charge density of the counter-ions, U = applied
voltage
The voltage dependence of σ eff is calculated by integrating this equation
sl
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 Simplifying assumption - the counter-ions are all located at a fixed distance
dH (of the order of a few nanometres) from the surface (Helmholtz model).

In this case, the double layer has a fixed capacitance per unit area,

ε oε1 CH= ρ / U
cH =
dH
Where ε1 is the dielectric constant of the liquid. γeffSL denotes the effective
surface tension at the liquid–solid interface

U
ε ε
γ SL
eff
γ SL − ∫ C H U d U =
(U ) = γ SL − 0 1 (U ) 2 (5)
U pzc
2d H

Upzc is the potential (difference) of zero charge and approximated to zero.

Mercury surfaces—like those of most other materials—acquire a spontaneous charge when
immersed into electrolyte solutions at zero voltage. The voltage required to compensate for
this spontaneous charging is Upzc
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 γLG cos θ = γSG − γSL

Young’s law applied successively at zero potential and at potential
V can be written

γSG − γSL = γLG cos θ0

γSG − γeffSL(V ) = γLG cos θ

where θ, θ0 are respectively the actuated and non-actuated contact
angles.

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 γLG cos θ = γSG − γSL
This equation for γ eff
sl
is inserted into Young’s equation.

For an electrolyte droplet placed directly on an electrode surface one can find
(Upzc approximated to zero)
ε 0 ε1
cosθ cosθY + (U )
2
= (6)
2d H σ lv
θY - equilibrium contact angle at zero applied voltage, ε0 - permittivity of free
space, ε1 - dielectric constant of the insulating layer, σlv -surface tension
between the liquid and the vapor, and U the applied voltage

For typical values of dH (2 nm), εl (81), and σlv (0.072 mJ m−2) the ratio on the
rhs of equation is on the order of 1 V−2.

The contact angle thus decreases rapidly upon the application of a voltage.

This equation is only applicable within a voltage range below the onset of
electrolytic processes, i.e. typically up to a few hundred millivolts.
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Modern applications of electrowetting usually circumvent this problem by introducing a
thin dielectric film, which insulates the droplet from the electrode.

In EWOD, the electric double layer builds up at the insulator–droplet interface.

Since the insulator thickness d is usually much larger than dH, the total capacitance of the
system is reduced tremendously.

The system may be described as two capacitors in series, namely the solid–insulator
interface (capacitance cH ) and the dielectric layer with
ε 0ε d
cd =
d
εd is the dielectric constant of the insulator.

Since c d