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Engineering Mathematics
Review of Viscous Flows
Review of Computational Fluid Mechanics
Review of Turbulence and Turbulence Modeling

Particle Adhesion
Colloids
Simulation Methods
Experimental Techniques
Applications
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The National Science Foundation
ME 637 The National Science Foundation
 Particle Adhesion
Van der Waals Force | JKR and Other Adhesion Models | Particle Adhesion & Removal | Effects of Charge | Effect of Humidity | Ultrasonic and Megasonic Cleaning

Effects of Charge

Conclusions

  • For small, spherical particles, adhesion appears to be dominated by van der Waals interactions.
  • As the particles become bigger or more irregular, electrostatics become more important.
  • Van der Waals interactions can be reduced, even for small, spherical particles, to the point where electrostatic forces can become dominant.
  • The electric charge contribution increases rapidly with increasing charge and the presence of neighboring particles.
  • These results hold for macroscopic systems as well as microscopic ones.
  • Electrostatic interactions are long-range.
  • JKR theory should be extended to allow for long-range interactions.

Dr. Goodarz Ahmadi | Turbulence & Multiphase Fluid Flow Laboratory | Department of Mechanical & Aeronautical Engineering
Copyright © 2002-2005 Dr. Goodarz Ahmadi. All rights reserved.
Potsdam, New York, 13699
ahmadi@clarkson.edu