Manipulation of Microbeads using DC/AC Electrical Fields By, Michael Scharrer Nitin Sharma Neil...
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Transcript of Manipulation of Microbeads using DC/AC Electrical Fields By, Michael Scharrer Nitin Sharma Neil...
Manipulation of Microbeads using DC/AC Electrical Fields
By,Michael ScharrerNitin SharmaNeil Krishnan
What is Dielectrophoresis?
Moment of Polarizable particles under the action of AC electrical field.
Forces Involved!! Deterministic forces
Dielectrophoretic Hydrodynamic Sedimentation
Random Brownian
Dielectrophoretic Force Gradient in electrical Field Volume of the particles Polarizability of the particles
Frequency of AC signal Negative and Positive
Dielectrophoresis
Electrohydrodynamic Forces Natural Convection
Density variation Coulomb
Charge gradients Dielectric
Permittivity gradients
Brownian Force
Gives a Gaussian Probability distribution to the particle.
Higher the time scale of observation more is the deterministic movement observed.
Procedure
Various configurations of electrodes available for creating electric field
Procedure First method – cover slide Second method – Droplet and probes Third method – Wafer flooding
First Method : Cover slide Use Gold electrodes Adjust probes to touch the contact pads of
electrodes Place a small droplet (2.5l) at the site of interest Cover with a cover slide cut to appropriate size
• Problems
• Evaporation
• Contact
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
• Don’t need to worry about contact
• Evaporation is much slower
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
Results and Discussion
Positive DEP was achieved once by Carmen and Changhong.
Result could not be repeated.
Conditions used:
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.
Problems
Complicated set-up (focusing, establishing contact, applying cover slide)
Lack of control over experimental variables (conductivity, voltage)
“Noise’ from excessive motion of beads
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.
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.