InfoCoBuild

Microfluidics

Microfluidics. Instructor: Prof. Suman Chakraborty, Department of Mechanical Engineering, IIT Kharagpur. Microfluidics is all about studying flows with characteristic length scales of the orders of microns. Microfluidics is an interdisciplinary field of engineering, physics, chemistry, biochemistry, nanotechnology, and biotechnology. Topics covered in this course include Introduction to microfluidics and application examples, Equations of conservation, Navier-Stokes equation, Energy equation, Pressure driven microflows, Lubrication theory, Boundary condition in fluid mechanics, Surface tension driven flows, Thin film dynamics, Electrokinetics, Nanofluidics, and Biomicrofluidics. (from nptel.ac.in)

Lecture 10 - Pressure Driven Microflows (cont.)


Go to the Course Home or watch other lectures:

Lecture 01 - Introduction to Microfluidics
Lecture 02 - Microfluidics: Some Application Examples
Lecture 03 - Microfluidics: Some More Application Examples
Lecture 04 - Equations of Conservation
Lecture 05 - Navier-Stokes Equation
Lecture 06 - Navier-Stokes Equation (cont.)
Lecture 07 - Energy Equation
Lecture 08 - Energy Equation (cont.), Species Conservation Equation
Lecture 09 - Pressure Driven Microflows
Lecture 10 - Pressure Driven Microflows (cont.)
Lecture 11 - Pressure Driven Microflows (cont.)
Lecture 12 - Pressure Driven Microflows (cont.)
Lecture 13 - Pressure Driven Microflows (cont.)
Lecture 14 - Some Examples of Steady Flows
Lecture 15 - Some Examples of Steady Flows (cont.)
Lecture 16 - Some Examples of Steady Flows (cont.)
Lecture 17 - Stokes Drag on a Sphere
Lecture 18 - Stokes Drag on a Sphere (cont.), Introduction to Lubrication Theory
Lecture 19 - Lubrication Theory (cont.)
Lecture 20 - Lubrication Theory (cont.)
Lecture 21 - Boundary Condition in Fluid Mechanics: Slip or Non-slip?
Lecture 22 - Boundary Condition in Fluid Mechanics: Slip or Non-slip? (cont.)
Lecture 23 - Surface Tension Driven Flows
Lecture 24 - Surface Tension Driven Flows (cont.)
Lecture 25 - Surface Tension Driven Flows (cont.)
Lecture 26 - Surface Tension Driven Flows (cont.)
Lecture 27 - Surface Tension Driven Flows (cont.), Modulating Surface Tension
Lecture 28 - Modulating Surface Tension (cont.)
Lecture 29 - Thin Film Dynamics
Lecture 30 - Thin Film Dynamics (cont.)
Lecture 31 - Thin Film Dynamics (cont.)
Lecture 32 - Thin Film Dynamics (cont.)
Lecture 33 - Lab on a CD
Lecture 34 - Lab on a CD (cont.)
Lecture 35 - Introduction to Microfabrication
Lecture 36 - Electrokinetics
Lecture 37 - Electrokinetics (cont.)
Lecture 38 - Electrokinetics (cont.)
Lecture 39 - Electrokinetics (cont.)
Lecture 40 - Electrokinetics (cont.)
Lecture 41 - Electrokinetics (cont.)
Lecture 42 - Dispersion
Lecture 43 - Introduction to Nanofluidics
Lecture 44 - Introduction to Nanofluidics (cont.), Molecular Dynamics Simulations
Lecture 45 - Introduction to Molecular Dynamics Simulations (cont.)
Lecture 46 - Biomicrofluidics
Lecture 47 - Biomicrofluidics (cont.)
Lecture 48 - Nanofluidic Energy Conversion