NPTEL : NOC:Transport Phenomena in Biological Systems (Biotechnology)

Co-ordinators : Prof. G.K. Suraishkumar


Lecture 1 - Introduction

Lecture 2 - Mass Conservation

Lecture 3 - Mass Conservation for a Macroscopic System

Lecture 4 - Mass Conservation for a Microscopic System

Lecture 5 - Useful Derivatives

Lecture 6 - Equation of Continuity

Lecture 7 - Mass Flux

Lecture 8 - Mass and Molar Fluxes

Lecture 9 - Shell Balance Approach

Lecture 10 - Continuity Equation Approach

Lecture 11 - Steady-state Diffusion

Lecture 12 - Steady-state Diffusion across Tubular Walls

Lecture 13 - Steady-state Radial Diffusion

Lecture 14 - Steady-state Diffusion with Reaction

Lecture 15 - Unsteady-state Diffusion

Lecture 16 - Unsteady-state Diffusion (Continued...)

Lecture 17 - Pseudo Steady State Approximation (Continued...)

Lecture 18 - Pseudo Steady State Approximation (Continued...)

Lecture 19 - Review of Mass Flux

Lecture 20 - Momentum Flux - Introduction

Lecture 21 - Rheology

Lecture 22 - Fluid Flow types

Lecture 23 - Shell Momentum Balances

Lecture 24 - Shell Momentum Balances (Continued...)

Lecture 25 - Equation of Motion

Lecture 26 - Equation of Motion (Continued...)

Lecture 27 - Application of Equation of Motion to Flow Over an Inclined Plane

Lecture 28 - Laminar Flow through a Pipe

Lecture 29 - Laminar Flow through a Pipe (Continued...)

Lecture 30 - Capillary Flow

Lecture 31 - Couette Flow

Lecture 32 - Non-dimensional Analysis

Lecture 33 - Unsteady State Flow

Lecture 34 - Unsteady State Flow (Continued...)

Lecture 35 - Pulsatile Flow

Lecture 36 - Turbulent Flow

Lecture 37 - Macroscopic Aspects: The Engineering Bernoulli Equation

Lecture 38 - Friction Factor for Flow through a Straight Horizontal Pipe

Lecture 39 - Application of the Engineering Bernoulli Equation to a Piping Network

Lecture 40 - Stenosis in an Artery

Lecture 41 - Friction Factor for Relative Motion between a Solid and a Liquid

Lecture 42 - Friction Factor for Packed Beds

Lecture 43 - Review of Momentum Flux

Lecture 44 - Review of Momentum Flux (Continued...)

Lecture 45 - Thermal Energy Flux

Lecture 46 - Equation of Energy

Lecture 47 - Temperature Profile in a Tissue

Lecture 48 - Unsteady-state Heat Conduction

Lecture 49 - Review of Heat Flux

Lecture 50 - Charge Flux

Lecture 51 - Charge Flux - Some Fundamentals

Lecture 52 - Charge Flux - Some More Fundamentals

Lecture 53 - Getting Useful Relationships through Maxwell's Equations

Lecture 54 - Charges/Ions in Solution

Lecture 55 - Charge Flux: Review

Lecture 56 - Fluxes Under Simultaneous, Multiple Driving Forces

Lecture 57 - Simultaneous Concentration Gradient and Electrical Potential Gradient

Lecture 58 - Mobility of Ions Across a Membrane

Lecture 59 - Electrical Circuit Representation of a Membrane

Lecture 60 - Action Potential and Axial Current

Lecture 61 - Electrophoresis

Lecture 62 - Simultaneous Concentration Gradient and Velocity Gradient

Lecture 63 - Simultaneous Concentration Gradient and Velocity Gradient - Bioreactor Kla

Lecture 64 - Gas-Liquid Interphase Transport

Lecture 65 - Gas-Liquid Interphase Transport (Continued...)

Lecture 66 - Bioreactor Kla Estimation

Lecture 67 - Liquid Phase Oxygen-Supply Strategy

Lecture 68 - LPOS and Its Mechanism

Lecture 69 - LPOS for Mold Cultivations

Lecture 70 - LPOS Optimization and Costs

Lecture 71 - Couette Flow Cultivations

Lecture 72 - Pseudo-Steady State Approximation Applied to Bio-oil Production

Lecture 73 - Pseudo-Steady State Approximation Applied to Cancer Treatment

Lecture 74 - Kinetics of a Process with an Enzyme Immobilized on a Non-porous Slab

Lecture 75 - Simultaneous Temperature Gradient and Velocity Gradient

Lecture 76 - Design of Heat Exchangers

Lecture 77 - Design of Heat Exchangers (Continued...)

Lecture 78 - Course Review - Part 1

Lecture 79 - Course Review - Part 2

Lecture 80 - Course Review - Part 3

Lecture 81 - Course Review - Part 4