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Manipulation of Microbeads using DC/AC Electrical Fields

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Title: Results and Discussion Author: mgs601 Last modified by: Preferred Customer Created Date: 3/20/2003 5:06:37 PM Document presentation format – PowerPoint PPT presentation

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Title: Manipulation of Microbeads using DC/AC Electrical Fields


1
Manipulation of Microbeads using DC/AC Electrical
Fields
  • By,
  • Michael Scharrer
  • Nitin Sharma
  • Neil Krishnan

2
What is Dielectrophoresis?
  • Moment of Polarizable particles under the action
    of AC electrical field.

3
Forces Involved!!
  • Deterministic forces
  • Dielectrophoretic
  • Hydrodynamic
  • Sedimentation
  • Random
  • Brownian

4
Dielectrophoretic Force
  • Gradient in electrical Field
  • Volume of the particles
  • Polarizability of the particles
  • Frequency of AC signal
  • Negative and Positive Dielectrophoresis

5
Electrohydrodynamic Forces
  • Natural Convection
  • Density variation
  • Coulomb
  • Charge gradients
  • Dielectric
  • Permittivity gradients

6
Brownian Force
  • Gives a Gaussian Probability distribution to the
    particle.
  • Higher the time scale of observation more is the
    deterministic movement observed.

7
Procedure
8
Procedure
  • First method cover slide
  • Second method Droplet and probes
  • Third method Wafer flooding

9
First Method Cover slide
  • Use Gold electrodes
  • Adjust probes to touch the contact pads of
    electrodes
  • Place a small droplet (2.5?l) at the site of
    interest
  • Cover with a cover slide cut to appropriate size
  • Problems
  • Evaporation
  • Contact

10
Second Method Droplet and Probes
  • Use probes as electrodes
  • Position probes to lie flat on cover slide
  • Place a large droplet (0.1 ml) at the site of
    interest
  • Advantage
  • Dont need to worry about contact
  • Evaporation is much slower

11
Third method Flooding wafer
  • Glass wafer with gold electrodes placed in a
    petri-dish
  • Petri-dish flooded with solution till wafer is
    immersed
  • Same as first procedure
  • Advantages
  • Evaporation effects are minimal
  • Beads are more stable
  • Disadvantages
  • Difficult to position probes
  • Difficult to see beads

12
Results and Discussion
  • Positive DEP was achieved once by Carmen and
    Changhong.
  • Result could not be repeated.
  • Conditions used

13
  • After changing the procedure by using the probes
    directly as electrodes, we got some accumulation
    of beads on the probe tips.
  • Excessive motion of beads made results unreliable
    and unrepeatable.

14
Problems
  • Complicated set-up (focusing, establishing
    contact, applying cover slide)
  • Lack of control over experimental variables
    (conductivity, voltage)
  • Noise from excessive motion of beads

15
Recommendations
  •  Implement measuring the conductivity of the
    buffer/beads solution.
  • (A set-up to do this for small amounts of liquid
    probably exists on campus. We tried to locate the
    necessary equipment but were not successful in
    the given time.)
  • Fabricate a glass cover to constrain the liquid
    in the electrode region, prevent quick
    evaporation and excessive motion of the beads.
  • This work was started, but not finished in time.
    It should be straightforward using microscope
    slides and glue.
  •  

16
  • Integrating the electrical probes on the
    microscope stage
  • This would allow the stage and viewing area to be
    moved after electrical contact has been
    established.
  • Redesign wafer to allow all electrodes to be
    contacted from the same pads
  • This would allow the probes to quickly be
    brought into contact after the liquid has been
    applied and the microscope has been focused.
  • Improve the adhesion of the Au electrodes on the
    wafer.
  • Currently the electrodes have a tendency to peel
    off at higher voltages (4V) which obviously
    limits the range of conditions that can be
    applied.
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