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Fluid Flow, Mass Transport, Physicochemical Phenomena In Microfluidics and Their Application in Lab-on-a-chip Devices. Brownian Motion, Scalar Transport, Taylor-aris Dispersion, Combined Advection-diffusion-reaction, Charged Solutions, Buffer Systems, On-chip Focusing and Separation Methods, Capillary Flows, Flow in Porous Media. Learning Outcomes# at The End of The Course The Studednt Will Know How To# 1. Formulate Flow Equations With Electric Forces. 2. Perform Scaling Analysis of Flow Equations. 3. Perform Taylor-aris Type Analysis For Dispersive Flows. 4. Implement Monte Carlo Simulations Of Particles For Dispersive Flows. 5. Design Optimal Conditions For Surface Reactions in Microchannels. 6. Formulate and Solve Transport Equations For Charged Solutions. 7. Derive The Net Neutrality Condition and Apply It to Electrokinetic Problems. 8. Design And Analyze Electrophoresis and Isotachophoresis Systems.

Faculty: Mechanical Engineering
|Undergraduate Studies |Graduate Studies

Pre-required courses

(34013 - Fluid Mechanics 1 and 34041 - Heat Transfer)

• Advanced transport phenomena : fluid mechanics and convective transport processes - Leal, L. Gary
• Advanced transport phenomena [electronic resource] : fluid mechanics and convective transport processes - Leal, L. Gary.
• Laminar flow and convective transport processes : scaling principles and asymptotic analysis - Leal, L. Gary
• Micro- and nanoscale fluid mechanics [electronic resource] : transport in microfluidic devices - Kirby, Brian
• Micro- and nanoscale fluid mechanics : transport in microfluidic devices - Kirby, Brian
• Physicochemical hydrodynamics : an introduction - Probstein, Ronald F.
• Physicochemical hydrodynamics [electronic resource] : an introduction - Probstein, Ronald F.
• Random walks in biology - Berg, Howard C.
• Random walks in biology [electronic resource] - Berg, Howard C.,
• Theoretical microfluidics - Bruus, Henrik.