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Chemical Engineering (4,971 Video Lectures)

Link	NPTEL Course Name	NPTEL Lecture Title
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 1 - Course Overview - I
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 2 - Course Overview - II
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 3 - Design Equations - I
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 4 - Design Equations - Illustrative Examples
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 5 - Design Equations - II : Plug Flow Recycle Reactors
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 6 - Illustrative Examples : 1) Plug Flow Recycle 2) Multiple reactions - I
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 7 - Illustrative Examples : 1) Recycle Reactor with Condenser 2) CSTR with Recycle
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 8 - Multiple Reactions - II
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 9 - Modelling Multiple Reactions in Soil Environment - III
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 10 - Semi Continuous Reactor Operation
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 11 - Catalyst Deactivation - I
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 12 - Catalyst Deactivation - II
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 13 - Illustrative Example : 1) Determination of deactivation Parameters 2) Design for Deactivating Catalyst
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 14 - Energy Balance - I
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 15 - Energy Balance - II
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 16 - Reacting Fluids as Energy Carrier
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 17 - Illustrative Example : Energy Balance in Stirred Vessels
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 18 - Energy Balance - III : Design for Constant T Operation
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 19 - Energy Balance - IV : Temperature Effects on Rate & Equilibria
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 20 - Energy Balance - V : Stability Analysis of Exothermic Stirred Tank
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 21 - Illustrative Example : Stability of Exothermic Stirred Tank
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 22 - Energy Balance - VI : 1) Tubular Reactor Heated/Cooled from Wall 2) Transient Behavior of CSTR
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 23 - Illustrative Example : 1) Plug Flow with Heat Effects 2) Multiple Reactions
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 24 - Illustrative Example : 1) Further Considerations in Energy Balance 2) Multiple Reactions
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 25 - Illustrative Example : 1) Hot Spot as Design Basis 2) Design for Instantaneous Reactions
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 26 - Residence Time Distribution Methods
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 27 - Residence Time Distribution Models
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 28 - Shrinking core Gas-Solid reactions Model
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 29 - Shrinking core Ash Diffusion Model & Combination of Resistances
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 30 - 1) Gas Solid Reactions Temperature Effects on Rate & Equilibria 2) Introduction to Population Balance - I
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 31 - Illustrative Example : Temperature Effects on Rate & Equilibria
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 32 - Population Balance Modelling - II
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 33 - Population Balance Modelling - III
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 34 - Illustrative Examples : Population Balance Models
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 35 - Introduction to Environmental Reactions
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 36 - Reaction Engineering Examples in Biochemical & Environmental Engineering
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 37 - Illustrative Examples : 1) Biomethanation 2) Alcohol via Fermentation 3) Natural Selection
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 38 - Illustrative Examples : 1) Enzyme Reaction 2) Microbial Reaction 3) Waste Treatment
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 39 - Oxygen Sag Analysis in Rivers
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 40 - Illustrative Examples : 1) Oxygen Sag Analysis 2) Population Balance Modelling of Forest 3) Sponge Iron Process
Link	Advanced Chemical Reaction Engineering (PG)	Lecture 41 - Illustrative Example : Gas- Solid Reaction RTD Models Reaction Network
Link	Advanced Process Control	Lecture 1 - Introduction and Motivation
Link	Advanced Process Control	Lecture 2 - Linearization of Mechanistic Models
Link	Advanced Process Control	Lecture 3 - Linearization of Mechanistic Models (Continued...)
Link	Advanced Process Control	Lecture 4 - Introduction to z-transforms and Development of Grey-box models
Link	Advanced Process Control	Lecture 5 - Introduction to Stability Analysis and Development of Output Error Models
Link	Advanced Process Control	Lecture 6 - Introduction to Stochastic Processes
Link	Advanced Process Control	Lecture 7 - Introduction to Stochastic Processes (Continued...)
Link	Advanced Process Control	Lecture 8 - Development of ARX models
Link	Advanced Process Control	Lecture 9 - Statistical Properties of ARX models and Development of ARMAX models
Link	Advanced Process Control	Lecture 10 - Development of ARMAX models (Continued...) and Issues in Model Development
Link	Advanced Process Control	Lecture 11 - Model Structure Selection and Issues in Model Development (Continued...)
Link	Advanced Process Control	Lecture 12 - Issues in Model Development (Continued...) and State Realizations of Transfer Function Models
Link	Advanced Process Control	Lecture 13 - Stability Analysis of Discrete Time Systems
Link	Advanced Process Control	Lecture 14 - Lyapunov Functions and Interaction Analysis and Multi-loop Control
Link	Advanced Process Control	Lecture 15 - Interaction Analysis and Multi-loop Control (Continued...)
Link	Advanced Process Control	Lecture 16 - Multivariable Decoupling Control and Soft Sensing and State Estimation
Link	Advanced Process Control	Lecture 17 - Development of Luenberger Observer
Link	Advanced Process Control	Lecture 18 - Development of Luenberger Observer (Continued...) and Introduction to Kalman Filtering
Link	Advanced Process Control	Lecture 19 - Kalman Filtering
Link	Advanced Process Control	Lecture 20 - Kalman Filtering (Continued...)
Link	Advanced Process Control	Lecture 21 - Kalman Filtering (Continued...)
Link	Advanced Process Control	Lecture 22 - Pole Placement State Feedback Control Design and Introduction to Linear Quadratic Gaussian (LQG) Control
Link	Advanced Process Control	Lecture 23 - Linear Quadratic Gaussian (LQG) Regulator Design
Link	Advanced Process Control	Lecture 24 - Linear Quadratic Gaussian (LQG) Controller Design
Link	Advanced Process Control	Lecture 25 - Model Predictive Control (MPC)
Link	Advanced Process Control	Lecture 26 - Model Predictive Control (Continued...)
Link	Chemical Reaction Engineering II	Lecture 1 - Introduction to catalysts and catalysis
Link	Chemical Reaction Engineering II	Lecture 2 - Steps in catalytic reaction: adsorption, desorption and reaction
Link	Chemical Reaction Engineering II	Lecture 3 - Derivation of the rate equation
Link	Chemical Reaction Engineering II	Lecture 4 - Heterogenous data analysis for reactor design - I
Link	Chemical Reaction Engineering II	Lecture 5 - Heterogenous data analysis for reactor design - II
Link	Chemical Reaction Engineering II	Lecture 6 - Catalyst deactivation and accounting for it in design - I
Link	Chemical Reaction Engineering II	Lecture 7 - Catalyst deactivation and accounting for it in design - II
Link	Chemical Reaction Engineering II	Lecture 8 - Synthesize the rate equation
Link	Chemical Reaction Engineering II	Lecture 9 - Introduction to intraparticle diffusion
Link	Chemical Reaction Engineering II	Lecture 10 - Intraparticle diffusion: Thiele modulus and effectiveness factor Part - I
Link	Chemical Reaction Engineering II	Lecture 11 - Intraparticle diffusion: Thiele modulus and effectiveness factor Part - II
Link	Chemical Reaction Engineering II	Lecture 12 - Intraparticle diffusion: Thiele modulus and effectiveness factor Part - III
Link	Chemical Reaction Engineering II	Lecture 13 - Effectiveness factor and Introduction to external mass transfer
Link	Chemical Reaction Engineering II	Lecture 14 - External Mass Transfer
Link	Chemical Reaction Engineering II	Lecture 15 - Implications to rate data interpretation and design - I
Link	Chemical Reaction Engineering II	Lecture 16 - Implications to rate data interpretation and design - II
Link	Chemical Reaction Engineering II	Lecture 17 - Packed-bed reactor design
Link	Chemical Reaction Engineering II	Lecture 18 - Fluidized bed reactor design - I
Link	Chemical Reaction Engineering II	Lecture 19 - Fluidized bed reactor design - II
Link	Chemical Reaction Engineering II	Lecture 20 - Gas-liquid reactions-1: Theories of mass transfer into agitated liquids
Link	Chemical Reaction Engineering II	Lecture 21 - GLR-2: Effect of chemical reaction on mass transfer: the slow reaction regime
Link	Chemical Reaction Engineering II	Lecture 22 - GLR-3: Transition to fast reaction, and the Fast reaction regime
Link	Chemical Reaction Engineering II	Lecture 23 - GLR-4: Fast reaction example; Instantaneous reaction regime
Link	Chemical Reaction Engineering II	Lecture 24 - GLR-5: Transition to Instantaneous reaction; Reaction regimes in surface renewal theories
Link	Chemical Reaction Engineering II	Lecture 25 - GLR-6: Reaction regimes in surface renewal theories (Continued..)
Link	Chemical Reaction Engineering II	Lecture 26 - GLR-7: Surface renewal theories: Instantaneous reaction and Summing up
Link	Chemical Reaction Engineering II	Lecture 27 - Fluid-solid non-catalytic reactions - I
Link	Chemical Reaction Engineering II	Lecture 28 - Fluid-solid non-catalytic reactions - II
Link	Chemical Reaction Engineering II	Lecture 29 - Fluid-solid non-catalytic reactions - III
Link	Chemical Reaction Engineering II	Lecture 30 - Distribution of residence time
Link	Chemical Reaction Engineering II	Lecture 31 - Measurement of residence time distribution
Link	Chemical Reaction Engineering II	Lecture 32 - Residence time distribution function
Link	Chemical Reaction Engineering II	Lecture 33 - Reactor diagnostics and troubleshooting
Link	Chemical Reaction Engineering II	Lecture 34 - Modeling non-ideal reactors
Link	Chemical Reaction Engineering II	Lecture 35 - Residence time distribution: Performance of non-ideal reactors
Link	Chemical Reaction Engineering II	Lecture 36 - Non-ideal Reactors: Tanks-in-series model
Link	Chemical Reaction Engineering II	Lecture 37 - Non-ideal Reactors: Dispersion model
Link	Chemical Reaction Engineering II	Lecture 38 - Non-ideal Reactors: Dispersion model and introduction to multiparameter models
Link	Chemical Reaction Engineering II	Lecture 39 - Non-ideal Reactors: Multiparameter models
Link	Advanced Numerical Analysis	Lecture 1 - Introduction and Overview
Link	Advanced Numerical Analysis	Lecture 2 - Fundamentals of Vector Spaces
Link	Advanced Numerical Analysis	Lecture 3 - Basic Dimension and Sub-space of a Vector Space
Link	Advanced Numerical Analysis	Lecture 4 - Introduction to Normed Vector Spaces
Link	Advanced Numerical Analysis	Lecture 5 - Examples of Norms,Cauchy Sequence and Convergence, Introduction to Banach Spaces
Link	Advanced Numerical Analysis	Lecture 6 - Introduction to Inner Product Spaces
Link	Advanced Numerical Analysis	Lecture 7 - Cauchy Schwaz Inequality and Orthogonal Sets
Link	Advanced Numerical Analysis	Lecture 8 - Gram-Schmidt Process and Generation of Orthogonal Sets
Link	Advanced Numerical Analysis	Lecture 9 - Problem Discretization Using Appropriation Theory
Link	Advanced Numerical Analysis	Lecture 10 - Weierstrass Theorem and Polynomial Approximation
Link	Advanced Numerical Analysis	Lecture 11 - Taylor Series Approximation and Newton's Method
Link	Advanced Numerical Analysis	Lecture 12 - Solving ODE - BVPs Using Firute Difference Method
Link	Advanced Numerical Analysis	Lecture 13 - Solving ODE - BVPs and PDEs Using Finite Difference Method
Link	Advanced Numerical Analysis	Lecture 14 - Finite Difference Method (Continued...) and Polynomial Interpolations
Link	Advanced Numerical Analysis	Lecture 15 - Polynomial and Function Interpolations,Orthogonal Collocations Method for Solving ODE -BVPs
Link	Advanced Numerical Analysis	Lecture 16 - Orthogonal Collocations Method for Solving ODE - BVPs and PDEs
Link	Advanced Numerical Analysis	Lecture 17 - Least Square Approximations, Necessary and Sufficient Conditions for Unconstrained Optimization
Link	Advanced Numerical Analysis	Lecture 18 - Least Square Approximations -Necessary and Sufficient Conditions for Unconstrained Optimization Least Square Approximations ( Continued....)
Link	Advanced Numerical Analysis	Lecture 19 - Linear Least Square Estimation and Geometric Interpretation of the Least Square Solution
Link	Advanced Numerical Analysis	Lecture 20 - Geometric Interpretation of the Least Square Solution (Continued...) and Projection Theorem in a Hilbert Spaces
Link	Advanced Numerical Analysis	Lecture 21 - Projection Theorem in a Hilbert Spaces (Continued...) and Approximation Using Orthogonal Basis
Link	Advanced Numerical Analysis	Lecture 22 - Discretization of ODE-BVP using Least Square Approximation
Link	Advanced Numerical Analysis	Lecture 23 - Discretization of ODE-BVP using Least Square Approximation and Gelarkin Method
Link	Advanced Numerical Analysis	Lecture 24 - Model Parameter Estimation using Gauss-Newton Method
Link	Advanced Numerical Analysis	Lecture 25 - Solving Linear Algebraic Equations and Methods of Sparse Linear Systems
Link	Advanced Numerical Analysis	Lecture 26 - Methods of Sparse Linear Systems (Continued...) and Iterative Methods for Solving Linear Algebraic Equations
Link	Advanced Numerical Analysis	Lecture 27 - Iterative Methods for Solving Linear Algebraic Equations
Link	Advanced Numerical Analysis	Lecture 28 - Iterative Methods for Solving Linear Algebraic Equations: Convergence Analysis using Eigenvalues
Link	Advanced Numerical Analysis	Lecture 29 - Iterative Methods for Solving Linear Algebraic Equations: Convergence Analysis using Matrix Norms
Link	Advanced Numerical Analysis	Lecture 30 - Iterative Methods for Solving Linear Algebraic Equations: Convergence Analysis using Matrix Norms (Continued...)
Link	Advanced Numerical Analysis	Lecture 31 - Iterative Methods for Solving Linear Algebraic Equations: Convergence Analysis (Continued...)
Link	Advanced Numerical Analysis	Lecture 32 - Optimization Based Methods for Solving Linear Algebraic Equations: Gradient Method
Link	Advanced Numerical Analysis	Lecture 33 - Conjugate Gradient Method, Matrix Conditioning and Solutions of Linear Algebraic Equations
Link	Advanced Numerical Analysis	Lecture 34 - Matrix Conditioning and Solutions and Linear Algebraic Equations (Continued...)
Link	Advanced Numerical Analysis	Lecture 35 - Matrix Conditioning (Continued...) and Solving Nonlinear Algebraic Equations
Link	Advanced Numerical Analysis	Lecture 36 - Solving Nonlinear Algebraic Equations: Wegstein Method and Variants of Newton's Method
Link	Advanced Numerical Analysis	Lecture 37 - Solving Nonlinear Algebraic Equations: Optimization Based Methods
Link	Advanced Numerical Analysis	Lecture 38 - Solving Nonlinear Algebraic Equations: Introduction to Convergence analysis of Iterative Solution Techniques
Link	Advanced Numerical Analysis	Lecture 39 - Solving Nonlinear Algebraic Equations: Introduction to Convergence analysis (Continued...) and Solving ODE-IVPs
Link	Advanced Numerical Analysis	Lecture 40 - Solving Ordinary Differential Equations - Initial Value Problems (ODE-IVPs) : Basic Concepts
Link	Advanced Numerical Analysis	Lecture 41 - Solving Ordinary Differential Equations - Initial Value Problems (ODE-IVPs) : Runge Kutta Methods
Link	Advanced Numerical Analysis	Lecture 42 - Solving ODE-IVPs : Runge Kutta Methods (Continued...) and Multi-step Methods
Link	Advanced Numerical Analysis	Lecture 43 - Solving ODE-IVPs : Generalized Formulation of Multi-step Methods
Link	Advanced Numerical Analysis	Lecture 44 - Solving ODE-IVPs : Multi-step Methods (Continued...) and Orthogonal Collocations Method
Link	Advanced Numerical Analysis	Lecture 45 - Solving ODE-IVPs: Selection of Integration Interval and Convergence Analysis of Solution Schemes
Link	Advanced Numerical Analysis	Lecture 46 - Solving ODE-IVPs: Convergence Analysis of Solution Schemes (Continued...)
Link	Advanced Numerical Analysis	Lecture 47 - Solving ODE-IVPs: Convergence Analysis of Solution Schemes (Continued...) and Solving ODE-BVP using Single Shooting Method
Link	Advanced Numerical Analysis	Lecture 48 - Methods for Solving System of Differential Algebraic Equations
Link	Advanced Numerical Analysis	Lecture 49 - Methods for Solving System of Differential Algebraic Equations (Continued...) and Concluding Remarks
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 1 - History of the theory of Natural Selection - 1
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 2 - History of the theory of Natural Selection - 2
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 3 - Exponential growth models
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 4 - Logistic Growth Models - 1
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 5 - Logistic Growth Models - 2
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 6 - Modelling selection - 1
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 7 - Modelling Selection - 2 : Two species
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 8 - Modelling Selection - 3 : Two and more species
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 9 - Modelling Mutations - 1
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 10 - Modelling Mutations - 2
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 11 - Modelling Mutations - 3
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 12 - Genetic Code and Sequence Spaces
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 13 - Sequence Spaces as Networks
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 14 - Sequence Space to Fitness Landscape
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 15 - Properties of Fitness Landscapes and Quasi-species
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 16 - Integrating Reproduction, Selection and Mutation
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 17 - Obtaining Fitness Landscapes Experimentally
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 18 - NK Model of Fitness Landscape
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 19 - Modelling Evolution on Fitness Landscapes - 1
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 20 - Modelling Evolution on Fitness Landscapes - 2
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 21 - Modelling Evolution on Fitness Landscapes - 3
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 22 - Role of Randomness in Evolution
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 23 - Genetic Drift in Evolution of Microbial Populations
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 24 - Dynamics of a Moran Process without Selection
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 25 - Dynamics of a Moran Process without Selection
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 26 - Evolution, Selection, and Genetic Drift
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 27 - Representing Microbial Evolution
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 28 - Estimating Timescales of Evolution
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 29 - Estimating the Speed of Microbial Evolution
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 30 - Evolutionary Dynamics when Mutations are Rare
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 31 - Evolutionary Dynamics when Mutations are Rapid - 1
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 32 - Evolutionary Dynamics when Mutations are Rapid - 2
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 33 - Evolutionary Dynamics when Mutations are Rapid - 3
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 34 - Evolutionary Game Theory - 1
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 35 - Evolutionary Game Theory - 2
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 36 - Evolutionary Game Theory - 3
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 37 - Evolutionary Game Theory - 4
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 38 - Evolutionary Game Theory Applied to Moran Process
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 39 - Evolutionary Games During Weak Selection
Link	NOC:Introduction to Evolutionary Dynamics	Lecture 40 - Evolutionary Dynamics of HIV
Link	NOC:Heat Transfer	Lecture 1 - Introduction
Link	NOC:Heat Transfer	Lecture 2 - Introduction to Conduction
Link	NOC:Heat Transfer	Lecture 3 - Energy Balance
Link	NOC:Heat Transfer	Lecture 4 - 1D Steadystate Conduction - Resistance Concept
Link	NOC:Heat Transfer	Lecture 5 - Resistances in Composite Wall Case
Link	NOC:Heat Transfer	Lecture 6 - Resistances in Radial Systems
Link	NOC:Heat Transfer	Lecture 7 - Heat Generation - I Plane and Cylindrical Wall
Link	NOC:Heat Transfer	Lecture 8 - Heat Generation - II Problem; Introduction to Extended Surfaces
Link	NOC:Heat Transfer	Lecture 9 - Extended Surfaces I - General Formulation
Link	NOC:Heat Transfer	Lecture 10 - Extended Surfaces II - Fixed Cross-section Area
Link	NOC:Heat Transfer	Lecture 11 - Extended Surfaces III - Varying Cross-section Area
Link	NOC:Heat Transfer	Lecture 12 - 2D Plane Wall
Link	NOC:Heat Transfer	Lecture 13 - Transient Analyses I : Lumped Capacitance Method
Link	NOC:Heat Transfer	Lecture 14 - Transient Analyses II : Full Method
Link	NOC:Heat Transfer	Lecture 15 - Transient Analyses : Semi-infinite Case
Link	NOC:Heat Transfer	Lecture 16 - Introduction to Convective Heat Transfer
Link	NOC:Heat Transfer	Lecture 17 - Heat and Mass Transport Coefficients
Link	NOC:Heat Transfer	Lecture 18 - Boundary Layer : Momentum, Thermal and Concentration
Link	NOC:Heat Transfer	Lecture 19 - Laminar and Turbulent Flows; Momentum Balance
Link	NOC:Heat Transfer	Lecture 20 - Energy and Mass Balances; Boundary Layer Approximations
Link	NOC:Heat Transfer	Lecture 21 - Order of Magnitude Analysis
Link	NOC:Heat Transfer	Lecture 22 - Transport Coefficients
Link	NOC:Heat Transfer	Lecture 23 - Relationship between Momentum, Thermal and Concentration Boundary Layer
Link	NOC:Heat Transfer	Lecture 24 - Reynolds and Chilton-Colburn Analogies
Link	NOC:Heat Transfer	Lecture 25 - Forced Convection : Introduction
Link	NOC:Heat Transfer	Lecture 26 - Flow Past Flat Plate I - Method of Blasius
Link	NOC:Heat Transfer	Lecture 27 - Flow Past Flat Plate II - Correlations for Heat and Mass Transport
Link	NOC:Heat Transfer	Lecture 28 - Flow Past Cylinders
Link	NOC:Heat Transfer	Lecture 29 - Flow through Pipes - I
Link	NOC:Heat Transfer	Lecture 30 - Flow through Pipes - II
Link	NOC:Heat Transfer	Lecture 31 - Flow through Pipes - III
Link	NOC:Heat Transfer	Lecture 32 - Flow through Pipes - IV - Mixing-cup Temperature
Link	NOC:Heat Transfer	Lecture 33 - Flow through Pipes - V - Log mean Temperature Difference
Link	NOC:Heat Transfer	Lecture 34 - Flow through Pipes - VI - Correlations for Laminar and Turbulent Conditions
Link	NOC:Heat Transfer	Lecture 35 - Example problems : Forced Convection
Link	NOC:Heat Transfer	Lecture 36 - Introduction to Free/Natural Convection
Link	NOC:Heat Transfer	Lecture 37 - Heated Plate in a Quiescent Fluid - I
Link	NOC:Heat Transfer	Lecture 38 - Heated Plate in a Quiescent Fluid - II
Link	NOC:Heat Transfer	Lecture 39 - Boiling - I
Link	NOC:Heat Transfer	Lecture 40 - Boiling - II
Link	NOC:Heat Transfer	Lecture 41 - Condensation - I
Link	NOC:Heat Transfer	Lecture 42 - Condensation - II
Link	NOC:Heat Transfer	Lecture 43 - Radiation : Introduction
Link	NOC:Heat Transfer	Lecture 44 - Spectral Intensity
Link	NOC:Heat Transfer	Lecture 45 - Radiation : Spectral properties, Blackbody
Link	NOC:Heat Transfer	Lecture 46 - Properties of a Blackbody
Link	NOC:Heat Transfer	Lecture 47 - Surface Adsorption
Link	NOC:Heat Transfer	Lecture 48 - Kirchoff’s Law
Link	NOC:Heat Transfer	Lecture 49 - Radiation Exchange - View Factor
Link	NOC:Heat Transfer	Lecture 50 - View Factor Examples
Link	NOC:Heat Transfer	Lecture 51 - View Factor - Inside Sphere Method, Blackbody Radiation Exchange
Link	NOC:Heat Transfer	Lecture 52 - Diffuse, Gray Surfaces in an Enclosure
Link	NOC:Heat Transfer	Lecture 53 - Resistances - Oppenheim Matrix Method
Link	NOC:Heat Transfer	Lecture 54 - Resistances - Examples
Link	NOC:Heat Transfer	Lecture 55 - More Examples: Volumetric Radiation
Link	NOC:Heat Transfer	Lecture 56 - Introduction and Examples
Link	NOC:Heat Transfer	Lecture 57 - Parallel Flow Heat Exchangers
Link	NOC:Heat Transfer	Lecture 58 - LMTD I
Link	NOC:Heat Transfer	Lecture 59 - Shell and Tube Heat Exchangers
Link	NOC:Heat Transfer	Lecture 60 - Epsilon-NTU Method
Link	NOC:Chemical Reaction Engineering-II	Lecture 1 - Introduction
Link	NOC:Chemical Reaction Engineering-II	Lecture 2 - Introduction to catalysis and catalytic processes
Link	NOC:Chemical Reaction Engineering-II	Lecture 3 - Catalyst properties and classification
Link	NOC:Chemical Reaction Engineering-II	Lecture 4 - Steps in catalysis
Link	NOC:Chemical Reaction Engineering-II	Lecture 5 - Adsorption isotherm
Link	NOC:Chemical Reaction Engineering-II	Lecture 6 - Surface reaction
Link	NOC:Chemical Reaction Engineering-II	Lecture 7 - Rate controlling steps and Rate law
Link	NOC:Chemical Reaction Engineering-II	Lecture 8 - Rate law: Pseudo-steady state hypothesis
Link	NOC:Chemical Reaction Engineering-II	Lecture 9 - Heterogeneous data analysis for reactor design - I
Link	NOC:Chemical Reaction Engineering-II	Lecture 10 - Heterogeneous data analysis for reactor design - II
Link	NOC:Chemical Reaction Engineering-II	Lecture 11 - Design of reactors: PBR and CSTR
Link	NOC:Chemical Reaction Engineering-II	Lecture 12 - Case study: Chemical Vapor Deposition
Link	NOC:Chemical Reaction Engineering-II	Lecture 13 - Catalyst deactivation - I
Link	NOC:Chemical Reaction Engineering-II	Lecture 14 - Catalyst deactivation - II
Link	NOC:Chemical Reaction Engineering-II	Lecture 15 - Catalyst deactivation - III
Link	NOC:Chemical Reaction Engineering-II	Lecture 16 - Catalyst deactivation - IV : Reactor design
Link	NOC:Chemical Reaction Engineering-II	Lecture 17 - Diffusional effects: Introduction
Link	NOC:Chemical Reaction Engineering-II	Lecture 18 - Internal diffusion effects: Model development
Link	NOC:Chemical Reaction Engineering-II	Lecture 19 - Non-dimensionalization: Thiele modulus
Link	NOC:Chemical Reaction Engineering-II	Lecture 20 - Concentration profile
Link	NOC:Chemical Reaction Engineering-II	Lecture 21 - Internal effectiveness factor - I
Link	NOC:Chemical Reaction Engineering-II	Lecture 22 - Internal effectiveness factor - II
Link	NOC:Chemical Reaction Engineering-II	Lecture 23 - Internal effectiveness factor - III: Exothermic and endothermic reactions
Link	NOC:Chemical Reaction Engineering-II	Lecture 24 - Falsification of kinetics
Link	NOC:Chemical Reaction Engineering-II	Lecture 25 - External mass transport limitations: Mass transfer coefficient
Link	NOC:Chemical Reaction Engineering-II	Lecture 26 - Estimation of mass transfer coefficient
Link	NOC:Chemical Reaction Engineering-II	Lecture 27 - Mass transfer to a single particle with reaction
Link	NOC:Chemical Reaction Engineering-II	Lecture 28 - Packed-bed reactor design: External mass transfer limitations
Link	NOC:Chemical Reaction Engineering-II	Lecture 29 - Mass transfer coefficient in Packed-beds
Link	NOC:Chemical Reaction Engineering-II	Lecture 30 - Estimation of conversion in Packed-bed reactor: Example problem
Link	NOC:Chemical Reaction Engineering-II	Lecture 31 - Overall effectiveness factor - I
Link	NOC:Chemical Reaction Engineering-II	Lecture 32 - Overall effectiveness factor - II
Link	NOC:Chemical Reaction Engineering-II	Lecture 33 - Identification of internal diffusion and reaction-limited regimes
Link	NOC:Chemical Reaction Engineering-II	Lecture 34 - Packed-bed reactor design
Link	NOC:Chemical Reaction Engineering-II	Lecture 35 - Generalized criterion for diffusion and reaction-limited conditions
Link	NOC:Chemical Reaction Engineering-II	Lecture 36 - Network of first order reactions
Link	NOC:Chemical Reaction Engineering-II	Lecture 37 - Use of experimental data
Link	NOC:Chemical Reaction Engineering-II	Lecture 38 - Packed-bed reactor design: External and Internal resistances
Link	NOC:Chemical Reaction Engineering-II	Lecture 39 - Fluidized bed reactor design - I
Link	NOC:Chemical Reaction Engineering-II	Lecture 40 - Fluidized bed reactor design - II
Link	NOC:Chemical Reaction Engineering-II	Lecture 41 - Fluidized bed reactor design - III
Link	NOC:Chemical Reaction Engineering-II	Lecture 42 - Fluidized bed reactor design - IV
Link	NOC:Chemical Reaction Engineering-II	Lecture 43 - Fluid-solid noncatalytic reactions - I
Link	NOC:Chemical Reaction Engineering-II	Lecture 44 - Fluid-solid noncatalytic reactions - II
Link	NOC:Chemical Reaction Engineering-II	Lecture 45 - Fluid-solid noncatalytic reactions - III
Link	NOC:Chemical Reaction Engineering-II	Lecture 46 - Fluid-solid noncatalytic reactions - IV
Link	NOC:Chemical Reaction Engineering-II	Lecture 47 - Fluid-solid noncatalytic reactions - V
Link	NOC:Chemical Reaction Engineering-II	Lecture 48 - Fluid-solid noncatalytic reactions - VI
Link	NOC:Chemical Reaction Engineering-II	Lecture 49 - Residence time distribution (RTD): Introduction
Link	NOC:Chemical Reaction Engineering-II	Lecture 50 - RTD: Non-ideal reactors
Link	NOC:Chemical Reaction Engineering-II	Lecture 51 - Measurement of RTD - I
Link	NOC:Chemical Reaction Engineering-II	Lecture 52 - Measurement of RTD - II
Link	NOC:Chemical Reaction Engineering-II	Lecture 53 - RTD function
Link	NOC:Chemical Reaction Engineering-II	Lecture 54 - Properties of RTD function
Link	NOC:Chemical Reaction Engineering-II	Lecture 55 - Reactor diagnostics and troubleshooting - I
Link	NOC:Chemical Reaction Engineering-II	Lecture 56 - Reactor diagnostics and troubleshooting - II
Link	NOC:Chemical Reaction Engineering-II	Lecture 57 - Modeling nonideal reactors - I
Link	NOC:Chemical Reaction Engineering-II	Lecture 58 - Modeling nonideal reactors - II
Link	NOC:Chemical Reaction Engineering-II	Lecture 59 - Non-ideal reactors: Zero parameter models - I
Link	NOC:Chemical Reaction Engineering-II	Lecture 60 - Non-ideal reactors: Zero parameter models - II
Link	NOC:Chemical Process Control	Lecture 1 - Motivation for process control
Link	NOC:Chemical Process Control	Lecture 2 - Functions of process control system
Link	NOC:Chemical Process Control	Lecture 3 - Common control strategies
Link	NOC:Chemical Process Control	Lecture 4 - Components of process control system
Link	NOC:Chemical Process Control	Lecture 5 - Introduction to process dynamics
Link	NOC:Chemical Process Control	Lecture 6 - First principle dynamic models
Link	NOC:Chemical Process Control	Lecture 7 - Empirical and gray box models
Link	NOC:Chemical Process Control	Lecture 8 - Degree of freedom analysis
Link	NOC:Chemical Process Control	Lecture 9 - Introduction to first order dynamical systems
Link	NOC:Chemical Process Control	Lecture 10 - Linearization of process dynamics
Link	NOC:Chemical Process Control	Lecture 11 - Response to step input
Link	NOC:Chemical Process Control	Lecture 12 - Response to sinusoidal input
Link	NOC:Chemical Process Control	Lecture 13 - Introduction to second order dynamical systems
Link	NOC:Chemical Process Control	Lecture 14 - Examples of second order dynamical systems
Link	NOC:Chemical Process Control	Lecture 15 - Response to step input
Link	NOC:Chemical Process Control	Lecture 16 - Effect of damping coefficient
Link	NOC:Chemical Process Control	Lecture 17 - Higher order dynamics
Link	NOC:Chemical Process Control	Lecture 18 - Approximation as FOPDT model
Link	NOC:Chemical Process Control	Lecture 19 - Numerator dynamics
Link	NOC:Chemical Process Control	Lecture 20 - Prediction of step response
Link	NOC:Chemical Process Control	Lecture 21 - Block diagram representation
Link	NOC:Chemical Process Control	Lecture 22 - ON-OFF control
Link	NOC:Chemical Process Control	Lecture 23 - Proportional control
Link	NOC:Chemical Process Control	Lecture 24 - Proportional-Integral control
Link	NOC:Chemical Process Control	Lecture 25 - PID control
Link	NOC:Chemical Process Control	Lecture 26 - Limitations of PID controllers
Link	NOC:Chemical Process Control	Lecture 27 - Stability of dynamical processes
Link	NOC:Chemical Process Control	Lecture 28 - Laplace domain analysis - Part I
Link	NOC:Chemical Process Control	Lecture 29 - Laplace domain analysis - Part II
Link	NOC:Chemical Process Control	Lecture 30 - Frequency response
Link	NOC:Chemical Process Control	Lecture 31 - Frequency domain analysis
Link	NOC:Chemical Process Control	Lecture 32 - Synthesis problem
Link	NOC:Chemical Process Control	Lecture 33 - Selection problem
Link	NOC:Chemical Process Control	Lecture 34 - Criteria-based controller tuning
Link	NOC:Chemical Process Control	Lecture 35 - Heuristics-based controller tuning
Link	NOC:Chemical Process Control	Lecture 36 - Direct synthesis-based controller tuning
Link	NOC:Chemical Process Control	Lecture 37 - Frequency response-based controller tuning
Link	NOC:Chemical Process Control	Lecture 38 - Cascade control
Link	NOC:Chemical Process Control	Lecture 39 - Split range control and override control
Link	NOC:Chemical Process Control	Lecture 40 - Auctioneering, ratio and inreferential control
Link	NOC:Chemical Process Control	Lecture 41 - Openloop control and Internal model control
Link	NOC:Chemical Process Control	Lecture 42 - Dynamic Matrix and Model predictive control
Link	NOC:Chemical Process Control	Lecture 43 - Introduction to multivariable control
Link	NOC:Chemical Process Control	Lecture 44 - Input-output pairing
Link	NOC:Chemical Process Control	Lecture 45 - Tuning of multi-loop SISO controller
Link	NOC:Chemical Process Control	Lecture 46 - Introduction to batch process control
Link	NOC:Chemical Process Control	Lecture 47 - Programmable logic control
Link	NOC:Chemical Process Control	Lecture 48 - Batch to batch control
Link	NOC:Introduction to Interfacial Waves	Lecture 1 - Introduction
Link	NOC:Introduction to Interfacial Waves	Lecture 2 - Coupled, linear, spring-mass systems
Link	NOC:Introduction to Interfacial Waves	Lecture 3 - Coupled, linear, spring-mass systems (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 4 - Coupled, linear, spring-mass systems (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 5 - Coupled, linear, spring-mass system: continuum limit
Link	NOC:Introduction to Interfacial Waves	Lecture 6 - Normal modes of a string fixed at both ends
Link	NOC:Introduction to Interfacial Waves	Lecture 7 - Vibrations of clamped membranes
Link	NOC:Introduction to Interfacial Waves	Lecture 8 - Vibrations of clamped membranes (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 9 - Introduction to Jacobian elliptic functions
Link	NOC:Introduction to Interfacial Waves	Lecture 10 - The non-linear pendulum
Link	NOC:Introduction to Interfacial Waves	Lecture 11 - The non-linear pendulum (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 12 - Time period of the non-linear pendulum
Link	NOC:Introduction to Interfacial Waves	Lecture 13 - Introduction to perturbation methods
Link	NOC:Introduction to Interfacial Waves	Lecture 14 - Perturbation methods (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 15 - Non-dimensionalisation
Link	NOC:Introduction to Interfacial Waves	Lecture 16 - Perturbative solution to the projectile equation
Link	NOC:Introduction to Interfacial Waves	Lecture 17 - Perturbative solution to the nonlinear pendulum
Link	NOC:Introduction to Interfacial Waves	Lecture 18 - Lindstedt-Poincare technique
Link	NOC:Introduction to Interfacial Waves	Lecture 19 - Method of multiple scales
Link	NOC:Introduction to Interfacial Waves	Lecture 20 - Method of multiple scales (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 21 - Multiple scale analysis for damped-harmonic oscillator
Link	NOC:Introduction to Interfacial Waves	Lecture 22 - Duffing equation using multiple scales
Link	NOC:Introduction to Interfacial Waves	Lecture 23 - Duffing equation (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 24 - Kapitza pendulum
Link	NOC:Introduction to Interfacial Waves	Lecture 25 - Introduction to Floquet theory
Link	NOC:Introduction to Interfacial Waves	Lecture 26 - Floquet theorem (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 27 - Floquet analysis of the Mathieu equation
Link	NOC:Introduction to Interfacial Waves	Lecture 28 - Introduction to waves on an interface
Link	NOC:Introduction to Interfacial Waves	Lecture 29 - Linearized wave equations in deep water
Link	NOC:Introduction to Interfacial Waves	Lecture 30 - Linearized wave equations in deep water: dispersion relation
Link	NOC:Introduction to Interfacial Waves	Lecture 31 - Linearised deep-water surface gravity waves (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 32 - Standing and travelling waves in deep water
Link	NOC:Introduction to Interfacial Waves	Lecture 33 - Cauchy-Poisson initial value problem for surface-gravity waves in deep water
Link	NOC:Introduction to Interfacial Waves	Lecture 34 - Cauchy-Poisson problem (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 35 - Cauchy-Poisson problem in cylindrical geometry
Link	NOC:Introduction to Interfacial Waves	Lecture 36 - Cauchy-Poisson problem in cylindrical geometry (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 37 - Group-velocity and the Cauchy-Poisson problem
Link	NOC:Introduction to Interfacial Waves	Lecture 38 - Cauchy-Poisson problem for delta function initial condition
Link	NOC:Introduction to Interfacial Waves	Lecture 39 - Cauchy-Poisson problem for delta function initial condition (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 40 - Capillary-gravity waves
Link	NOC:Introduction to Interfacial Waves	Lecture 41 - Waves on a pool of finite depth
Link	NOC:Introduction to Interfacial Waves	Lecture 42 - Axisymmetric Cauchy-Poisson problem visualisation: the pebble in the deep pond problem
Link	NOC:Introduction to Interfacial Waves	Lecture 43 - Rayleigh-Plateau capillary instability
Link	NOC:Introduction to Interfacial Waves	Lecture 44 - Rayleigh-Plateau capillary instability (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 45 - Rayleigh-Plateau capillary instability on thin film coating a rod
Link	NOC:Introduction to Interfacial Waves	Lecture 46 - Rayleigh-Plateau capillary instability of a cylindrical air column in a liquid
Link	NOC:Introduction to Interfacial Waves	Lecture 47 - Mechanism of the Rayleigh-Plateau instability
Link	NOC:Introduction to Interfacial Waves	Lecture 48 - Shape oscillations of a spherical interface
Link	NOC:Introduction to Interfacial Waves	Lecture 49 - Shape oscillations of a spherical interface (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 50 - Shape oscillations of a spherical interface (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 51 - Analysis of l=0 and l=1 modes for a spherical drop
Link	NOC:Introduction to Interfacial Waves	Lecture 52 - Faraday waves on an interface - stability of time dependent base states
Link	NOC:Introduction to Interfacial Waves	Lecture 53 - Mathieu equation for Faraday waves
Link	NOC:Introduction to Interfacial Waves	Lecture 54 - Applications of Faraday waves - atomisation and spray formation
Link	NOC:Introduction to Interfacial Waves	Lecture 55 - Waves and instability on density stratified shear flows - the KH model
Link	NOC:Introduction to Interfacial Waves	Lecture 56 - Limits of KH dispersion relation: Rayleigh-Taylor instability
Link	NOC:Introduction to Interfacial Waves	Lecture 57 - KH dispersion relation : model of wind wave generation
Link	NOC:Introduction to Interfacial Waves	Lecture 58 - Helmholtz instability of a vortex sheet and summary
Link	NOC:Introduction to Interfacial Waves	Lecture 59 - Derivation of the Stokes travelling wave
Link	NOC:Introduction to Interfacial Waves	Lecture 60 - Derivation of the Stokes travelling wave (Continued...)
Link	NOC:Introduction to Interfacial Waves	Lecture 61 - Derivation of the Stokes travelling wave (Continued...)
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 1
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 2
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 3
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 4
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 5
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 6
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 7
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 8
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 9
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 10
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 11
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 12
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 13
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 14
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 15
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 16
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 17
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 18
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 19
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 20
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 21
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 22
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 23
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 24
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 25
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 26
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 27
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 28
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 29
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 30
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 31
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 32
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 33
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 34
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 35
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 36
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 37
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 38
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 39
Link	Heterogeneous Catalysis and Catalytic Processes	Lecture 40
Link	Interfacial Engineering	Lecture 1 - General Introduction Definitions
Link	Interfacial Engineering	Lecture 2 - General Introduction, Definitions, Surface Tension
Link	Interfacial Engineering	Lecture 3 - Surface Tension Free Energies and Adsorption
Link	Interfacial Engineering	Lecture 4 - Properties over Curved Surfaces
Link	Interfacial Engineering	Lecture 5 - Total Surface Energy
Link	Interfacial Engineering	Lecture 6 - Interfacial Tension Entropy, Cohesion, Adhesion
Link	Interfacial Engineering	Lecture 7 - Cohesion, Adhesion and Spreading
Link	Interfacial Engineering	Lecture 8 - Spreading from Liquids and Solids
Link	Interfacial Engineering	Lecture 9 - Spreading, Interfacial Tensions, Surface Tensions
Link	Interfacial Engineering	Lecture 10 - Spreading, Contact Angles Free Energies
Link	Interfacial Engineering	Lecture 11 - Spreading/Contact Angles Rough Surfaces, Free Energies
Link	Interfacial Engineering	Lecture 12 - Spreading/Contact Angles Work of Adhesion, De-wetting
Link	Interfacial Engineering	Lecture 13 - Work of Adhesion, Surface and Interfacial Tensions
Link	Interfacial Engineering	Lecture 14 - Surface and Interfacial Tensions: Drop Weight and Wilhelmy Plate Methods
Link	Interfacial Engineering	Lecture 15 - Surface and Interfacial Tensions: Wilhelmy Plate, Pendant Drop and Maximum Bubble Pressure Methods
Link	Interfacial Engineering	Lecture 16 - Wetting Balance Method Spreading Coefficient Work of Adhesion Sessile Drop Method, Positive S
Link	Interfacial Engineering	Lecture 17 - Indirect and Direct Methods for Positive S, Adhesion Energies Interfacial Potentials
Link	Interfacial Engineering	Lecture 18 - Surface and Interfacial Potentials Distribution and Contact Potentials
Link	Interfacial Engineering	Lecture 19 - Diffusion Potential Surface and Interfacial Potentials Components of Contact Potential
Link	Interfacial Engineering	Lecture 20 - Electrically Charged Monolayers Gouy Theory
Link	Interfacial Engineering	Lecture 21 - Equations of State, Cohesion Repulsion, Limiting Area
Link	Interfacial Engineering	Lecture 22 - Condensed and Liquid Expanded Monolayers Phase Transformations
Link	Interfacial Engineering	Lecture 23 - Films of Polymers Molecular Weight, Surface Viscosity Drag, Canal Method
Link	Interfacial Engineering	Lecture 24 - Canal Method Joly's Semi-Empirical Correction Rotational Torsional Surface Viscometer Compressional Moduli
Link	Interfacial Engineering	Lecture 25 - Magnitudes of Surface Compressional Moduli Surface Waves and Ripples
Link	Interfacial Engineering	Lecture 26 - Surface waves and Ripples, Velocity Effect of Surface Tension and Surface Compressional Modulus Rates of adsorption and absorption Damping
Link	Interfacial Engineering	Lecture 27 - Surface waves and ripples,velocity effect of surface tension and surface compressional modulus damping for clean and contaminated,surfaces,fiber from monolayers
Link	Interfacial Engineering	Lecture 28 - Shear Elastic Moduli,Yield Stress Fibres from MLs, Surface Reactions
Link	Interfacial Engineering	Lecture 29 - Surface Reactions, Comparison with Bulk-Phase Reactions Steric Factors, Inhibition
Link	Interfacial Engineering	Lecture 30 - Hydrolyses of Esters by Alkali Acid or Enzyme Photochemical Reactions in Monolayers Polymerization in MLs, Lactonization
Link	Interfacial Engineering	Lecture 31 - Catalytic Effects Reactions in Emulsions Complex Formation
Link	Interfacial Engineering	Lecture 32 - Complex Formation Penetration into Monolayers Thermodynamics of Penetration Adsorption from Vapour Phase Mass Transfer
Link	Interfacial Engineering	Lecture 33 - Introductory Concepts Resistances and their Magnitudes Evaporation and its Retardation
Link	Interfacial Engineering	Lecture 34 - Evaporation and its Retardation Resistances and their Analysis Diffusional Resistance in Gas Phase
Link	Interfacial Engineering	Lecture 35 - Resistances in Liquid Phase and Interface and Their Importance Some Effects and Applications, Theory
Link	Interfacial Engineering	Lecture 36 - Surface Instability Theories of Mass Transfer Experiments on static and Dynamic Systems
Link	Interfacial Engineering	Lecture 37 - Colloida, Aerosols, Emulsions Foams, Coagulation Smoluchowski's Theory
Link	NOC:Fluid Mechanics and its Applications	Lecture 1 (1)
Link	NOC:Fluid Mechanics and its Applications	Lecture 2 (1A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 3 (2)
Link	NOC:Fluid Mechanics and its Applications	Lecture 4 (2A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 5 (3)
Link	NOC:Fluid Mechanics and its Applications	Lecture 6 (3A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 7 (4)
Link	NOC:Fluid Mechanics and its Applications	Lecture 8 (4A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 9 (5)
Link	NOC:Fluid Mechanics and its Applications	Lecture 10 (5A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 11 (6)
Link	NOC:Fluid Mechanics and its Applications	Lecture 12 (6A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 13 (7)
Link	NOC:Fluid Mechanics and its Applications	Lecture 14 (7A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 15 (8)
Link	NOC:Fluid Mechanics and its Applications	Lecture 16 (8A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 17 (8B)
Link	NOC:Fluid Mechanics and its Applications	Lecture 18 (9)
Link	NOC:Fluid Mechanics and its Applications	Lecture 19 (9A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 20 (10)
Link	NOC:Fluid Mechanics and its Applications	Lecture 21 (10A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 22 (10B)
Link	NOC:Fluid Mechanics and its Applications	Lecture 23 (11)
Link	NOC:Fluid Mechanics and its Applications	Lecture 24 (12)
Link	NOC:Fluid Mechanics and its Applications	Lecture 25 (12A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 26 (12B)
Link	NOC:Fluid Mechanics and its Applications	Lecture 27 (13)
Link	NOC:Fluid Mechanics and its Applications	Lecture 28 (13A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 29 (14)
Link	NOC:Fluid Mechanics and its Applications	Lecture 30 (14A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 31 (15)
Link	NOC:Fluid Mechanics and its Applications	Lecture 32 (15A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 33 (16)
Link	NOC:Fluid Mechanics and its Applications	Lecture 34 (16A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 35 (17)
Link	NOC:Fluid Mechanics and its Applications	Lecture 36 (17A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 37 (18)
Link	NOC:Fluid Mechanics and its Applications	Lecture 38 (18A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 39 (19)
Link	NOC:Fluid Mechanics and its Applications	Lecture 40 (19A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 41 (20)
Link	NOC:Fluid Mechanics and its Applications	Lecture 42 (20A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 43 (20B)
Link	NOC:Fluid Mechanics and its Applications	Lecture 44 (21)
Link	NOC:Fluid Mechanics and its Applications	Lecture 45 (21A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 46 (22)
Link	NOC:Fluid Mechanics and its Applications	Lecture 47 (22A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 48 (23)
Link	NOC:Fluid Mechanics and its Applications	Lecture 49 (23A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 50 (24)
Link	NOC:Fluid Mechanics and its Applications	Lecture 51 (24A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 52 (25)
Link	NOC:Fluid Mechanics and its Applications	Lecture 53 (25A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 54 (26)
Link	NOC:Fluid Mechanics and its Applications	Lecture 55 (26A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 56 (25)
Link	NOC:Fluid Mechanics and its Applications	Lecture 57 (27)
Link	NOC:Fluid Mechanics and its Applications	Lecture 58 (28)
Link	NOC:Fluid Mechanics and its Applications	Lecture 59 (28A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 60 (29)
Link	NOC:Fluid Mechanics and its Applications	Lecture 61 (29A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 62 (30)
Link	NOC:Fluid Mechanics and its Applications	Lecture 63 (30A)
Link	NOC:Fluid Mechanics and its Applications	Lecture 64 (31)
Link	NOC:Fluid Mechanics and its Applications	Lecture 65 (31A)
Link	Heat Transfer	Lecture 1 - Introduction to heat transfer
Link	Heat Transfer	Lecture 2 - General heat conduction equation
Link	Heat Transfer	Lecture 3 - One dimensional steady state conduction in rectangular coordinate
Link	Heat Transfer	Lecture 4 - One dimensional steady state conduction in cylindrical and spherical coordinate
Link	Heat Transfer	Lecture 5 - Critical and optimum insulation
Link	Heat Transfer	Lecture 6 - Extended surface heat transfer - 1
Link	Heat Transfer	Lecture 7 - Extended surface heat transfer - 2
Link	Heat Transfer	Lecture 8 - Analysis of lumped parameter model
Link	Heat Transfer	Lecture 9 - Transient heat flow in semi infinite solid
Link	Heat Transfer	Lecture 10 - Infinite body subjected to sudden convective
Link	Heat Transfer	Lecture 11 - Graphical solutions of unsteady state heat conduction problem
Link	Heat Transfer	Lecture 12 - Dimensional analysis for forced convection
Link	Heat Transfer	Lecture 13 - Dimensional analysis for free convection
Link	Heat Transfer	Lecture 14 - Heat transfer co-relations for laminar and internal flows
Link	Heat Transfer	Lecture 15 - Heat transfer co-relations for turbulent and internal flows
Link	Heat Transfer	Lecture 16 - Co-relation for turbulent and external flows
Link	Heat Transfer	Lecture 17 - Heat transfer co-relations for flow across tube banks
Link	Heat Transfer	Lecture 18 - Momentum and heat transfer analogies
Link	Heat Transfer	Lecture 19 - Boundary layer heat transfer
Link	Heat Transfer	Lecture 20 - Boundary layer equations
Link	Heat Transfer	Lecture 21 - Approximate analysis in boundary layer
Link	Heat Transfer	Lecture 22 - Theoretical concepts of natural / free convention heat transfer
Link	Heat Transfer	Lecture 23 - Emperical relations for free convention heat transfer
Link	Heat Transfer	Lecture 24 - Condensation heat transfer over vertical plate
Link	Heat Transfer	Lecture 25 - Condensation heat transfer for various conditions and geometries
Link	Heat Transfer	Lecture 26 - Fundamentals of boiling heat transfer
Link	Heat Transfer	Lecture 27 - Boiling heat transfer co-relations
Link	Heat Transfer	Lecture 28 - Classification of heat exchangers
Link	Heat Transfer	Lecture 29 - Various types of shell and tube heat exchangers
Link	Heat Transfer	Lecture 30 - Various types of compact heat exchangers
Link	Heat Transfer	Lecture 31 - Effectiveness-NTU, method of heat exchanger analysis
Link	Heat Transfer	Lecture 32 - Design of double pipe heat exchanger
Link	Heat Transfer	Lecture 33 - Design of shell and tube heat exchanger
Link	Heat Transfer	Lecture 34 - Introduction to evaporation and evaporators
Link	Heat Transfer	Lecture 35 - Evaporation principles and evaporator performance
Link	Heat Transfer	Lecture 36 - Evaporator calculations
Link	Heat Transfer	Lecture 37 - Introduction to radiation heat transfer
Link	Heat Transfer	Lecture 38 - Radiation intensity and radiation view factor
Link	Heat Transfer	Lecture 39 - Radiation heat exchange
Link	Heat Transfer	Lecture 40 - Radiation shield and gas radiation
Link	Mass Transfer Operations I	Lecture 1 - Introduction to Mass Transfer
Link	Mass Transfer Operations I	Lecture 2 - Molecular Diffusion
Link	Mass Transfer Operations I	Lecture 3 - Fick’s Law of Diffusion
Link	Mass Transfer Operations I	Lecture 4 - Steady state molecular diffusion in fluids - Part I
Link	Mass Transfer Operations I	Lecture 5 - Steady state molecular diffusion in fluids - Part II
Link	Mass Transfer Operations I	Lecture 6 - Diffusion coefficient: Measurement and Prediction - Part I
Link	Mass Transfer Operations I	Lecture 7 - Diffusion Coefficient: Measurement and Prediction - Part II
Link	Mass Transfer Operations I	Lecture 8 - Multicomponent Diffusion and Diffusivity in Solids
Link	Mass Transfer Operations I	Lecture 9 - Concept of Mass Transfer Coefficient
Link	Mass Transfer Operations I	Lecture 10 - Dimensionless Groups and Co-relations for Convective
Link	Mass Transfer Operations I	Lecture 11 - Mass Transfer co-efficient in Laminar Flow Condition
Link	Mass Transfer Operations I	Lecture 12 - Boundary Layer Theory and Film Theory in Mass Transfer
Link	Mass Transfer Operations I	Lecture 13 - Mass Transfer Coefficients in Terbulant Flow
Link	Mass Transfer Operations I	Lecture 14 - Interphase Mass Transfer and Mass Transfer Theories - Part I
Link	Mass Transfer Operations I	Lecture 15 - Interphase Mass Transfer and Mass Transfer Theories - Part II
Link	Mass Transfer Operations I	Lecture 16 - Interphase Mass Transfer and Mass Transfer Theories - Part III
Link	Mass Transfer Operations I	Lecture 17 - Agitated and Sparged Vassels
Link	Mass Transfer Operations I	Lecture 18 - Tray Column - Part I
Link	Mass Transfer Operations I	Lecture 19 - Tray Column - Part II
Link	Mass Transfer Operations I	Lecture 20 - Packed Tower
Link	Mass Transfer Operations I	Lecture 21 - Introduction to Absorption and Solvent selection
Link	Mass Transfer Operations I	Lecture 22 - Packed Tower Design - Part I
Link	Mass Transfer Operations I	Lecture 23 - Packed Tower Design - Part II
Link	Mass Transfer Operations I	Lecture 24 - Packed Tower Design - Part III
Link	Mass Transfer Operations I	Lecture 25 - Mass Transfer Coefficients Correlation and HETP Concept
Link	Mass Transfer Operations I	Lecture 26 - Tray Tower Design and Introduction to Multicomponent System
Link	Mass Transfer Operations I	Lecture 27 - Introduction to Distillation and Phas diagrams
Link	Mass Transfer Operations I	Lecture 28 - Azeotropes and Enthalpy Concentration Diagrams
Link	Mass Transfer Operations I	Lecture 29 - Flash Distillation
Link	Mass Transfer Operations I	Lecture 30 - Batch and Steam Distillation
Link	Mass Transfer Operations I	Lecture 31 - Fractional Distillation
Link	Mass Transfer Operations I	Lecture 32 - Fractional Distillation: McCabe Thiele Method
Link	Mass Transfer Operations I	Lecture 33 - Fractional Distillation: Minimum Reflux and Pinch Point
Link	Mass Transfer Operations I	Lecture 34 - Fractional Distillation: Subcooled Reflux ,Tray Efficiency and Use of Open Steam
Link	Mass Transfer Operations I	Lecture 35 - Fractional Distillation: Multiple Feeds and Side Stream
Link	Mass Transfer Operations I	Lecture 36 - Multistage Batch Distillation with Reflux
Link	Mass Transfer Operations I	Lecture 37 - Fractional Distillation: Ponchan and Savarit Method
Link	Mass Transfer Operations I	Lecture 38 - Ponchan and Savarit Method and Packed Tower Distillation
Link	Mass Transfer Operations I	Lecture 39 - Multicomponent Distillation
Link	Process Design Decisions and Project Economics	Lecture 1 - General Introduction to the Course and Syllabus
Link	Process Design Decisions and Project Economics	Lecture 2 - Hierarchical Approach to Process Design - I
Link	Process Design Decisions and Project Economics	Lecture 3 - Hierarchical Approach to Process Design - Examples
Link	Process Design Decisions and Project Economics	Lecture 4 - Input Information and Design Aspects of Batch vs. Continuous Process
Link	Process Design Decisions and Project Economics	Lecture 5 - Input / Output Structure of Flowsheet - Part I
Link	Process Design Decisions and Project Economics	Lecture 6 - Input / Output Structure of Flowsheet - Part II
Link	Process Design Decisions and Project Economics	Lecture 7 - Input / Output Structure of Flowsheet - Part III and Recycle Structure of Flowsheet - Part I
Link	Process Design Decisions and Project Economics	Lecture 8 - Recycle Structure of Flowsheet - Part II
Link	Process Design Decisions and Project Economics	Lecture 9 - Recycle Structure of Flowsheet - Part III
Link	Process Design Decisions and Project Economics	Lecture 10 - Recycle Structure of Flowsheet - Part IV and Tutorial - Part I
Link	Process Design Decisions and Project Economics	Lecture 11 - Tutorial - Part II
Link	Process Design Decisions and Project Economics	Lecture 12 - Tutorial - Part III
Link	Process Design Decisions and Project Economics	Lecture 13 - Algorithm and Basic Principles of Reactor Design
Link	Process Design Decisions and Project Economics	Lecture 14 - Reactor Non-ideality, Residence Time Distribution (RTD) and Types of Chemical Reactions & Catalysts
Link	Process Design Decisions and Project Economics	Lecture 15 - Types of Reactors and Selection Criteria
Link	Process Design Decisions and Project Economics	Lecture 16 - Tutorial on Reactor Design and Cost Estimation
Link	Process Design Decisions and Project Economics	Lecture 17 - General Introduction (Types of Separation Processes and Criteria for Selection of the Processes)
Link	Process Design Decisions and Project Economics	Lecture 18 - Guidelines for Design of Separation Systems
Link	Process Design Decisions and Project Economics	Lecture 19 - Design of Distillation Columns - Part I (Sequencing of Columns, Energy Integration / Thermal Coupling of the Columns)
Link	Process Design Decisions and Project Economics	Lecture 20 - Design of Distillation Columns - Part II (Plate and Packed Towers, Number of Plates, Diameter and Height of the Column)
Link	Process Design Decisions and Project Economics	Lecture 21 - Tutorial - Part I (Design of Absorption Column)
Link	Process Design Decisions and Project Economics	Lecture 22 - Tutorial - Part II (Design of Distillation Column)
Link	Process Design Decisions and Project Economics	Lecture 23 - Concepts and Basic Principles of Energy (or Heat) Integration - Part 1 (Composite Curves and ?Tmin)
Link	Process Design Decisions and Project Economics	Lecture 24 - Concepts and Basic Principles of Heat Integration - Part 2 (Problem Table Algorithm and Identification of Energy Targets)
Link	Process Design Decisions and Project Economics	Lecture 25 - Identification of Area and Cost Targets
Link	Process Design Decisions and Project Economics	Lecture 26 - Pinch Technology for Heat Exchanger Network Design
Link	Process Design Decisions and Project Economics	Lecture 27 - Tutorial - I (Composite Curves, Problem Table Algorithm and Enthalpy Intervals)
Link	Process Design Decisions and Project Economics	Lecture 28 - Tutorial - II (Heat Exchanger Network Synthesis Using Pinch Technology)
Link	Process Design Decisions and Project Economics	Lecture 29 - Selection of Process, Design of Flowsheet and Materials Balance
Link	Process Design Decisions and Project Economics	Lecture 30 - Energy Balance, Process Alternatives and Design of the Absorber
Link	Process Design Decisions and Project Economics	Lecture 31 - Rules of Thumb & Their Limitations and Tutorial
Link	Process Design Decisions and Project Economics	Lecture 32 - General Concepts & Principles and Cost Allocation Procedure
Link	Process Design Decisions and Project Economics	Lecture 33 - Lumped Cost Diagram and Cost Allocation Diagram (Case Study of Hydro-dealkylation Process)
Link	Process Design Decisions and Project Economics	Lecture 34 - Assessment of Process Alternatives with Cost Allocation Diagram (Case Study of Hydrodealkylation Process)
Link	Process Design Decisions and Project Economics	Lecture 35 - Tutorial on Lumped Cost Diagram and Cost Allocation Diagram
Link	Process Design Decisions and Project Economics	Lecture 36 - Introduction to Chemical Projects and Their Economic Aspects
Link	Process Design Decisions and Project Economics	Lecture 37 - Selection of the Process and Project Site - Part I
Link	Process Design Decisions and Project Economics	Lecture 38 - Selection of the Process and Project Site - Part II
Link	Process Design Decisions and Project Economics	Lecture 39 - Project Cost Estimation - Part I
Link	Process Design Decisions and Project Economics	Lecture 40 - Project Cost Estimation - Part II
Link	Process Design Decisions and Project Economics	Lecture 41 - Simplified Cost Model and Depreciation
Link	Process Design Decisions and Project Economics	Lecture 42 - Time Value of Money
Link	Process Design Decisions and Project Economics	Lecture 43 - Measures of Profitability and Project Evaluation - Part I
Link	Process Design Decisions and Project Economics	Lecture 44 - Measures of Profitability and Project Evaluation - Part II
Link	Process Design Decisions and Project Economics	Lecture 45 - Tutorial on Project Economics - Part I
Link	Process Design Decisions and Project Economics	Lecture 46 - Tutorial on Project Economics - Part II
Link	NOC:Fluidization Engineering	Lecture 1 - Introduction
Link	NOC:Fluidization Engineering	Lecture 2 - Particle properties
Link	NOC:Fluidization Engineering	Lecture 3 - Particle / Powder Classifications
Link	NOC:Fluidization Engineering	Lecture 4 - Minimum Fluidization Velocity: Fluid-solid System
Link	NOC:Fluidization Engineering	Lecture 5 - Minimum Fluidization Velocity: Liquid-solid and gas-liquid-solid System
Link	NOC:Fluidization Engineering	Lecture 6 - Flow regime and its map: Gas-solid Fluidization
Link	NOC:Fluidization Engineering	Lecture 7 - Flow regime and its map: Liquid-solid and Gas-liquid-solid Fluidization
Link	NOC:Fluidization Engineering	Lecture 8 - Frictional pressure drop in fluidized bed-fluid-solid system
Link	NOC:Fluidization Engineering	Lecture 9 - Frictional pressure drop in fluidized Bed-Gas-liquid-solid system
Link	NOC:Fluidization Engineering	Lecture 10 - Analysis of Frictional Pressure Drop in Fluidized Bed By Different Models
Link	NOC:Fluidization Engineering	Lecture 11 - Gas Distribution Through Distributor
Link	NOC:Fluidization Engineering	Lecture 12 - Calculation of gas pumping power consumption in fluidized bed
Link	NOC:Fluidization Engineering	Lecture 13 - Bubbling Fluidization Part 1: Bubble Characteristics
Link	NOC:Fluidization Engineering	Lecture 14 - Bubbling Fluidization Part 2: Bubble Characteristics (Continued...)
Link	NOC:Fluidization Engineering	Lecture 15 - Bubbling Fluidization Part 3: Bubble coalescence in three-phase fluidization
Link	NOC:Fluidization Engineering	Lecture 16 - Bubbling Fluidization Part 4: Bubble breakup in three-phase fluidization
Link	NOC:Fluidization Engineering	Lecture 17 - Bubbling Fluidization Part 5: Gas and solid movements at bubble
Link	NOC:Fluidization Engineering	Lecture 18 - Bubbling Fluidization Part 6: Slugging Bed
Link	NOC:Fluidization Engineering	Lecture 19 - Entrainment Characteristics (Part 1) : Entrainment Characteristics
Link	NOC:Fluidization Engineering	Lecture 20 - Entrainment Characteristics (Part 2) : Fast fluidization condition
Link	NOC:Fluidization Engineering	Lecture 21 - Entrainment Characteristics (Part 2) : Elutriation Characteristics
Link	NOC:Fluidization Engineering	Lecture 22 - Entrainment Characteristics (Part 2) : Attrition in Fluidized Bed (Part 1)
Link	NOC:Fluidization Engineering	Lecture 23 - Attrition in Fluidized Bed (Part 2)
Link	NOC:Fluidization Engineering	Lecture 24 - Solid movement, mixing: Gas-fluidized Bed
Link	NOC:Fluidization Engineering	Lecture 25 - Solid segregation: Gas-fluidized bed
Link	NOC:Fluidization Engineering	Lecture 26 - Solid mixing and segregation: Liquid-solid fluidized bed
Link	NOC:Fluidization Engineering	Lecture 27 - Gas Dispersion and Interchange
Link	NOC:Fluidization Engineering	Lecture 28 - Mass transfer in fluidized Bed-Gas-solid system
Link	NOC:Fluidization Engineering	Lecture 29 - Mass transfer in fluidized Bed-Gas-liquid-solid system (Continued...)
Link	NOC:Fluidization Engineering	Lecture 30 - Heat transfer Characteristics
Link	NOC:Fluidization Engineering	Lecture 31 - Fluidized bed reactor design and its performance
Link	NOC:An Introduction to Cardiovascular Fluid Mechanics	Lecture 1 - An Introduction
Link	NOC:An Introduction to Cardiovascular Fluid Mechanics	Lecture 2 - Fluid Mechanics: A Review
Link	NOC:An Introduction to Cardiovascular Fluid Mechanics	Lecture 3 - Solid Mechanics: A Review
Link	NOC:An Introduction to Cardiovascular Fluid Mechanics	Lecture 4 - Rheology of blood
Link	NOC:An Introduction to Cardiovascular Fluid Mechanics	Lecture 5 - Blood morphology
Link	NOC:An Introduction to Cardiovascular Fluid Mechanics	Lecture 6 - Blood flow in a channel
Link	NOC:An Introduction to Cardiovascular Fluid Mechanics	Lecture 7 - Viscometers and Rheometers
Link	NOC:An Introduction to Cardiovascular Fluid Mechanics	Lecture 8 - Viscoelasticity
Link	NOC:An Introduction to Cardiovascular Fluid Mechanics	Lecture 9 - Flow Bifurcation
Link	NOC:An Introduction to Cardiovascular Fluid Mechanics	Lecture 10 - Pulsatile Flow 1
Link	NOC:An Introduction to Cardiovascular Fluid Mechanics	Lecture 11 - Pulsatile Flow 2
Link	NOC:An Introduction to Cardiovascular Fluid Mechanics	Lecture 12 - Flow in Elastic Tubes
Link	NOC:Multiphase Microfluidics	Lecture 1 - An Introduction
Link	NOC:Multiphase Microfluidics	Lecture 2 - Interface and Surface Tension
Link	NOC:Multiphase Microfluidics	Lecture 3 - Flow Regimes 1
Link	NOC:Multiphase Microfluidics	Lecture 4 - Flow Regimes 2
Link	NOC:Multiphase Microfluidics	Lecture 5 - Taylor Flow 1
Link	NOC:Multiphase Microfluidics	Lecture 6 - Taylor Flow 2
Link	NOC:Multiphase Microfluidics	Lecture 7 - Computational Techniques
Link	NOC:Multiphase Microfluidics	Lecture 8 - Bubble and Droplet Generation
Link	NOC:Multiphase Microfluidics	Lecture 9 - Interface and Surface tension 2
Link	NOC:Multiphase Microfluidics	Lecture 10 - Void Fraction and Pressure Drop
Link	NOC:Multiphase Microfluidics	Lecture 11 - Liquid-Liquid Flow: Flow Regimes
Link	NOC:Multiphase Microfluidics	Lecture 12 - Ideal annular Flow
Link	NOC:Multiphase Microfluidics	Lecture 13 - Taylor Flow : Heat transfer 1
Link	NOC:Multiphase Microfluidics	Lecture 14 - Taylor Flow : Heat transfer 2
Link	NOC:Multiphase Microfluidics	Lecture 15 - Taylor Flow : Meat Transfer 1
Link	NOC:Multiphase Microfluidics	Lecture 16 - Taylor Flow : Meat Transfer 2
Link	NOC:Multiphase Microfluidics	Lecture 17 - Flow boiling in microchannels
Link	NOC:Multiphase Microfluidics	Lecture 18 - Flow boiling in microchannels (Continued...)
Link	NOC:Multiphase Microfluidics	Lecture 19 - Flow Measurement Techniques
Link	NOC:Multiphase Microfluidics	Lecture 20 - Particle image Velocimetry
Link	NOC:Multiphase Microfluidics	Lecture 21 - Inertial Microfluidics
Link	NOC:Multiphase Microfluidics	Lecture 22 - Microfluidic applications
Link	NOC:Multiphase Microfluidics	Lecture 23 - Microfluidic applications (Continued...)
Link	NOC:Multiphase Microfluidics	Lecture 24 - Concluding Remarks
Link	NOC:Measurement Technique in Multiphase Flows	Lecture 1 - Introduction to Multiphase flow Measurement Techniques
Link	NOC:Measurement Technique in Multiphase Flows	Lecture 2 - Invasive and Non-invasive Techniques
Link	NOC:Measurement Technique in Multiphase Flows	Lecture 3 - Hot Wire Anemometry
Link	NOC:Measurement Technique in Multiphase Flows	Lecture 4 - Optical Fiber Probe
Link	NOC:Measurement Technique in Multiphase Flows	Lecture 5 - Laser Doppler Anemometry (LDA)
Link	NOC:Measurement Technique in Multiphase Flows	Lecture 6 - LDA Post Processing and Particle Image Velocimetry (PIV)
Link	NOC:Measurement Technique in Multiphase Flows	Lecture 7 - PIV and Positron Emission Particle Tracking
Link	NOC:Measurement Technique in Multiphase Flows	Lecture 8 - Radioactive Particle Tracking - I
Link	NOC:Measurement Technique in Multiphase Flows	Lecture 9 - Radioactive Particle Tracking - II
Link	NOC:Measurement Technique in Multiphase Flows	Lecture 10 - Capacitance Probe, Optical Fiber Probe and ECT
Link	NOC:Measurement Technique in Multiphase Flows	Lecture 11 - Gamma-ray and X-ray Tomography, MRI
Link	NOC:Measurement Technique in Multiphase Flows	Lecture 12 - Summary
Link	NOC:Multiphase Flows	Lecture 1 - Multiphase flow introduction
Link	NOC:Multiphase Flows	Lecture 2 - Fundamental definitions and terminology used in Multiphase - I
Link	NOC:Multiphase Flows	Lecture 3 - Fundamental definitions and terminology used in Multiphase - II
Link	NOC:Multiphase Flows	Lecture 4 - Flow Regime Map for Gas-Liquid System
Link	NOC:Multiphase Flows	Lecture 5 - Flow Regime Map for Fluid-Solid System
Link	NOC:Multiphase Flows	Lecture 6 - Pneumatic Conveying
Link	NOC:Multiphase Flows	Lecture 7 - Momentum Equation through Reynolds Transport Theorem
Link	NOC:Multiphase Flows	Lecture 8 - Lockhart Martinelli Correlation
Link	NOC:Multiphase Flows	Lecture 9 - Pressure Drop Calculation for Homogeneous Flow
Link	NOC:Multiphase Flows	Lecture 10 - Pressure Drop Calculation for Separated and Annular Flow Regime
Link	NOC:Multiphase Flows	Lecture 11 - Lagrangian Tracking of Single Particle Under Different Forces
Link	NOC:Multiphase Flows	Lecture 12 - Multiphase Interactions: Drag Force
Link	NOC:Multiphase Flows	Lecture 13 - Multiphase Interactions: Multi-particle Drag, Virtual Mass Force, Basset Force and Lift Force
Link	NOC:Multiphase Flows	Lecture 14 - Introduction to Multiphase Flow Modeling
Link	NOC:Multiphase Flows	Lecture 15 - Algebraic Slip Method and Euler-Euler Method
Link	NOC:Multiphase Flows	Lecture 16 - KTGF and Euler-Lagrangian Model
Link	NOC:Multiphase Flows	Lecture 17 - Measurement Techniques: Velocity Measurement
Link	NOC:Multiphase Flows	Lecture 18 - Measurement Techniques: Phase Fraction Measurement
Link	NOC:Multiphase Flows	Lecture 19 - Bubble Column
Link	NOC:Multiphase Flows	Lecture 20 - Packed Bed Reactor
Link	NOC:Multiphase Flows	Lecture 21 - Fluidized Bed Reactor
Link	NOC:Multiphase Flows	Lecture 22 - Summary
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 1 - Introduction to Polymers
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 2 - Ideal Chain Models
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 3 - Ideal and Real Chains
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 4 - Thermodynamics of Polymer Solutions - I
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 5 - Thermodynamics of Polymer Solutions - II
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 6 - Thermodynamics of Polymer Solutions - III
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 7 - Phase Behaviour of Polymer Solutions and Blends
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 8 - Phase Behaviour of Polymer Blends and Copolymers
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 9 - Determination of Polymer Molar Mass: Osmometry
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 10 - Determination of Polymer Molar Mass: Static Light Scattering - I
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 11 - Determination of Polymer Molar Mass: Static Light Scattering - II
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 12 - Determination of Polymer Molar Mass: Viscometry and GPC
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 13 - Branching: Hyperbranched Polymers
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 14 - Branching, Network Formation and Gelation
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 15 - Gelation and Swelling of Network Polymers
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 16 - Amorphous State of Polymers
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 17 - Crystalline State of Polymers
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 18 - Mechanical Properties of Polymers
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 19 - Viscoelasticity: Mechanical Models
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 20 - Viscoelasticity, Dynamic Mechanical Analysis and Rheology
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 21 - Rubber Elasticity
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 22 - Unentangled Polymer Dynamics
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 23 - Entangled Polymer Dynamics
Link	NOC:Introduction to Polymer Physics (IIT-G)	Lecture 24 - Review
Link	NOC:Natural Gas Engineering	Lecture 1 - Introduction to Natural Gas - I
Link	NOC:Natural Gas Engineering	Lecture 2 - Introduction to Natural Gas - II
Link	NOC:Natural Gas Engineering	Lecture 3 - Introduction to Natural Gas - III
Link	NOC:Natural Gas Engineering	Lecture 4 - Properties of Natural Gas-I
Link	NOC:Natural Gas Engineering	Lecture 5 - Properties of Natural Gas-II
Link	NOC:Natural Gas Engineering	Lecture 6 - Properties of Reservoir
Link	NOC:Natural Gas Engineering	Lecture 7 - Inflow Performance Relationship (IPR) - I
Link	NOC:Natural Gas Engineering	Lecture 8 - Inflow Performance Relationship (IPR) - II
Link	NOC:Natural Gas Engineering	Lecture 9 - Gas Well Testing
Link	NOC:Natural Gas Engineering	Lecture 10 - Wellbore Performance Relationship (WPR)
Link	NOC:Natural Gas Engineering	Lecture 11 - Choke Performance Relationship (CPR)
Link	NOC:Natural Gas Engineering	Lecture 12 - Nodal Analysis
Link	NOC:Natural Gas Engineering	Lecture 13 - Natural Gas Separation - I
Link	NOC:Natural Gas Engineering	Lecture 14 - Natural Gas Separation - II
Link	NOC:Natural Gas Engineering	Lecture 15 - Dehydration of Natural Gas
Link	NOC:Natural Gas Engineering	Lecture 16 - Sweeting of Natural Gas
Link	NOC:Natural Gas Engineering	Lecture 17 - Compressor Design
Link	NOC:Natural Gas Engineering	Lecture 18 - Measurement of Natural Gas
Link	NOC:Natural Gas Engineering	Lecture 19 - Transportation of Natural Gas - I
Link	NOC:Natural Gas Engineering	Lecture 20 - Transportation of Natural Gas - II
Link	NOC:Natural Gas Engineering	Lecture 21 - Unconventional production of Natural Gas
Link	NOC:Natural Gas Engineering	Lecture 22 - Review: Concluding Remarks
Link	NOC:Chemical Engineering Thermodynamics	Lecture 1 - Introduction
Link	NOC:Chemical Engineering Thermodynamics	Lecture 2 - First law for closed systems
Link	NOC:Chemical Engineering Thermodynamics	Lecture 3 - First law for open systems
Link	NOC:Chemical Engineering Thermodynamics	Lecture 4 - Simple processes
Link	NOC:Chemical Engineering Thermodynamics	Lecture 5 - Processes involving liquids and ideal gases
Link	NOC:Chemical Engineering Thermodynamics	Lecture 6 - Temperature dependency of Cp in an ideal gas
Link	NOC:Chemical Engineering Thermodynamics	Lecture 7 - Efficiency of Heat engines and Statement of Second Law
Link	NOC:Chemical Engineering Thermodynamics	Lecture 8 - Entropy
Link	NOC:Chemical Engineering Thermodynamics	Lecture 9 - Lost Work
Link	NOC:Chemical Engineering Thermodynamics	Lecture 10 - Maxwell's Relations
Link	NOC:Chemical Engineering Thermodynamics	Lecture 11 - Thermodynamic Diagrams
Link	NOC:Chemical Engineering Thermodynamics	Lecture 12 - Thermodynamic Tables, Residual Properties
Link	NOC:Chemical Engineering Thermodynamics	Lecture 13 - Virial Equation of State
Link	NOC:Chemical Engineering Thermodynamics	Lecture 14 - Residual property relations from EoS
Link	NOC:Chemical Engineering Thermodynamics	Lecture 15 - Cubic Equation of State
Link	NOC:Chemical Engineering Thermodynamics	Lecture 16 - Cubic Equation of State
Link	NOC:Chemical Engineering Thermodynamics	Lecture 17 - Thermodynamic Tables
Link	NOC:Chemical Engineering Thermodynamics	Lecture 18 - Correlations for Liquids
Link	NOC:Chemical Engineering Thermodynamics	Lecture 19 - Process Involving Phase Changes
Link	NOC:Chemical Engineering Thermodynamics	Lecture 20 - Chemical potential
Link	NOC:Chemical Engineering Thermodynamics	Lecture 21 - Partial molar properties
Link	NOC:Chemical Engineering Thermodynamics	Lecture 22 - Examples
Link	NOC:Chemical Engineering Thermodynamics	Lecture 23 - Ideal Solutions
Link	NOC:Chemical Engineering Thermodynamics	Lecture 24 - Excess Properties
Link	NOC:Chemical Engineering Thermodynamics	Lecture 25 - Fugacity
Link	NOC:Chemical Engineering Thermodynamics	Lecture 26 - Calculation of Fugacity using EoS - Part 1
Link	NOC:Chemical Engineering Thermodynamics	Lecture 27 - Calculation of Fugacity using EoS - Part 2
Link	NOC:Chemical Engineering Thermodynamics	Lecture 28 - Calculation of Fugacity in Mixtures using Cubic EoS
Link	NOC:Chemical Engineering Thermodynamics	Lecture 29 - Fugacity in Liquids, Activity Coeffcient
Link	NOC:Chemical Engineering Thermodynamics	Lecture 30 - Models for Excess Gibbs free energy - Part 1
Link	NOC:Chemical Engineering Thermodynamics	Lecture 31 - Models for Excess Gibbs free energy - Part 2
Link	NOC:Chemical Engineering Thermodynamics	Lecture 32 - Vapor Liquid Equilibrium - Part 1
Link	NOC:Chemical Engineering Thermodynamics	Lecture 33 - Vapor Liquid Equilibrium - Part 2
Link	NOC:Chemical Engineering Thermodynamics	Lecture 34 - Azeotropes
Link	NOC:Chemical Engineering Thermodynamics	Lecture 35 - Gamma/Phi Formulation
Link	NOC:Chemical Engineering Thermodynamics	Lecture 36 - LLE
Link	NOC:Chemical Engineering Thermodynamics	Lecture 37 - VLLE
Link	NOC:Chemical Engineering Thermodynamics	Lecture 38 - Enthalpy changes upon reaction
Link	NOC:Chemical Engineering Thermodynamics	Lecture 39 - Reaction coordinate
Link	NOC:Chemical Engineering Thermodynamics	Lecture 40 - Equilibrium constant
Link	NOC:Chemical Engineering Thermodynamics	Lecture 41 - Examples
Link	NOC:Chemical Engineering Thermodynamics	Lecture 42 - Conclusion
Link	NOC:Mass Transfer Operations-I	Lecture 1 - Introduction and Overview of Mass Transfer Operation
Link	NOC:Mass Transfer Operations-I	Lecture 2 - Molecular and Eddy Diffusion, Diffusion Velocities and Fluxes
Link	NOC:Mass Transfer Operations-I	Lecture 3 - Fick's First and Second Law
Link	NOC:Mass Transfer Operations-I	Lecture 4 - Steady State Molecular Diffusion in fluids under stagnant and laminar flow conditions
Link	NOC:Mass Transfer Operations-I	Lecture 5 - Diffusion through variable cross-sectional area
Link	NOC:Mass Transfer Operations-I	Lecture 6 - Gas Phase Diffusion Coefficient measurement
Link	NOC:Mass Transfer Operations-I	Lecture 7 - Gas Phase Diffusion Coefficient prediction and liquid phase diffusion coefficient measurement and prediction
Link	NOC:Mass Transfer Operations-I	Lecture 8 - Multicomponent diffusion and diffusivity in solids
Link	NOC:Mass Transfer Operations-I	Lecture 9 - Mass transfer coefficient concept and classifications
Link	NOC:Mass Transfer Operations-I	Lecture 10 - Dimensionless groups and correlations for convective mass transfer coefficients
Link	NOC:Mass Transfer Operations-I	Lecture 11 - Mass transfer coefficient in laminar flow
Link	NOC:Mass Transfer Operations-I	Lecture 12 - Boundary Layer Theory and mass transfer coefficients in turbulent flow
Link	NOC:Mass Transfer Operations-I	Lecture 13 - Mass transfer theories
Link	NOC:Mass Transfer Operations-I	Lecture 14 - Interphase mass transfer
Link	NOC:Mass Transfer Operations-I	Lecture 15 - Interphase mass transfer and material balance for operating line
Link	NOC:Mass Transfer Operations-I	Lecture 16 - Number of ideal stages in counter current operation: graphical and algebraic methods
Link	NOC:Mass Transfer Operations-I	Lecture 17 - Introduction, classification, Sparged and agitated vessels design
Link	NOC:Mass Transfer Operations-I	Lecture 18 - Gas dispersed: Tray tower
Link	NOC:Mass Transfer Operations-I	Lecture 19 - Sieve Tray
Link	NOC:Mass Transfer Operations-I	Lecture 20 - Liquid dispersed: Venture scrubber, wetted wall column, Packed tower
Link	NOC:Mass Transfer Operations-I	Lecture 21 - Introduction to absorption, Equilibrium in gas-liquid system, and minimum liquid rate
Link	NOC:Mass Transfer Operations-I	Lecture 22 - Design of packed column absorber based on the Individual Mass Transfer Coefficient
Link	NOC:Mass Transfer Operations-I	Lecture 23 - Design of packed column absorber based on the Overall Mass Transfer Coefficient
Link	NOC:Mass Transfer Operations-I	Lecture 24 - Height Equivalent to a Theoretical Plate (HETP), Design of packed column absorber for dilute and concentrated gases
Link	NOC:Mass Transfer Operations-I	Lecture 25 - Absorption in plate column: Method of McCabe and Thiele-graphical determination of ideal trays and Introduction to multicomponent absorption
Link	NOC:Mass Transfer Operations-I	Lecture 26 - Introduction to distillation, binary equilibrium diagrams and concept of relative volatility
Link	NOC:Mass Transfer Operations-I	Lecture 27 - Distillation in non-ideal systems and concept of enthalpy-concentration diagram
Link	NOC:Mass Transfer Operations-I	Lecture 28 - Flash distillation
Link	NOC:Mass Transfer Operations-I	Lecture 29 - Batch and steam distillation
Link	NOC:Mass Transfer Operations-I	Lecture 30 - Continuous multistate fractionation
Link	NOC:Mass Transfer Operations-I	Lecture 31 - Number of trays by McCabe and Thiele for distillation
Link	NOC:Mass Transfer Operations-I	Lecture 32 - Pinch Points and minimum reflux
Link	NOC:Mass Transfer Operations-I	Lecture 33 - Reflux below its bubble point: Sub-cooled reflux and use of open steam
Link	NOC:Mass Transfer Operations-I	Lecture 34 - Multiple feeds, multiple product withdrawal or side streams
Link	NOC:Mass Transfer Operations-I	Lecture 35 - Multistage batch distillation with reflux
Link	NOC:Mass Transfer Operations-I	Lecture 36 - The Ponchon-Savarit method
Link	NOC:Mass Transfer Operations-I	Lecture 37 - The Ponchon-Savarit method
Link	NOC:Mass Transfer Operations-I	Lecture 38 - Packed Distillation
Link	NOC:Mass Transfer Operations-I	Lecture 39 - Introduction to multicomponent distillation and multicomponent flash distillation
Link	NOC:Mass Transfer Operations-I	Lecture 40 - Minimum stages and minimum reflux in multicomponent distillation
Link	NOC:Mass Transfer Operations-I	Lecture 41 - Multicomponent batch distillation
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 1 - Introduction and Basic Concepts
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 2 - Classification of Non-Newtonian Fluids
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 3 - Mathematical Models for Non-Newtonian Fluids
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 4 - Viscoelastic Non-Newtonian Fluids
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 5 - Capillary Viscometers: Sources of Errors and Correction Methods
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 6 - Rotational Viscometers
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 7 - Capillary Viscometers - Errors and Corrections II
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 8 - Equation of Change for Non-Isothermal Systems
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 9 - Rotational Viscometers - II
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 10 - Rotational Viscometers - III
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 11 - Transition from Laminar to Turbulent Flow in Pipes for GNF
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 12 - Equations of Change for Isothermal Systems
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 13 - Equations of Change for Non-Isothermal Systems
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 14 - Power-law Fluids Flow in Concentric Annulus
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 15 - Power-law and Ellis Model Fluids Flow Through Pipes
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 16 - Bingham Plastic Fluids Flow through Pipes
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 17 - Herschel Bulkley Fluids Flow through Pipes
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 18 - Transition and Turbulent Flow of GNF in Pipes - I
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 19 - Transition and Turbulent Flow of GNF in Pipes - II
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 20 - Laminar flow of GNFs between Parallel Plates and along Inclined Surface
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 21 - Laminar flow of GNFs along Inclined Surface and Concentric Annulus
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 22 - Flow of Non-Newtonian Fluids through Packed Beds
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 23 - Dispersion in Packed Beds: Non-Newtonian Effects
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 24 - Liquid-Solid Fluidization by Power-law Liquids
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 25 - Free Convection between Two Vertical Plates
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 26 - Viscous Heat Generation
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 27 - Temperature distribution in fluids confined between co-axial cylinders
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 28 - Temperature distribution for FDF of Newtonian fluids in tubes
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 29 - Heat Transfer Combined with Chemical Reactions
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 30 - Transpiration Cooling
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 31 - Basics of MT; Diffusion Through Stagnant Gas Film
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 32 - Non-Isothermal Diffusive MT and Forced Convective MT
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 33 - Simultaneous Heat and Mass Transfer
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 34 - Mass Transfer Combined with Chemical Reactions
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 35 - Quasi-Steady Analysis of Simultaneous HT, MT and Chemical Reaction
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 36 - Quasi-Steady Analysis of Simultaneous HT and MT - I
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 37 - Quasi-Steady Analysis of Simultaneous HT and MT - II
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 38 - Quasi-Steady Analysis of Simultaneous HT and MT - III
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 39 - Momentum and Thermal Boundary Layer Flows
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 40 - Momentum Boundary Layer Thickness of Non-Newtonian Fluids
Link	NOC:Transport Phenomena of Non-Newtonian Fluids	Lecture 41 - Thermal and Concentration Boundary Layer Thickness of Non-Newtonian Fluids
Link	NOC:Fluid Flow Operations	Lecture 1 - Introduction
Link	NOC:Fluid Flow Operations	Lecture 2 - Characteristics of fluid (Continued...)
Link	NOC:Fluid Flow Operations	Lecture 3 - Fluid Statics
Link	NOC:Fluid Flow Operations	Lecture 4 - Fluid Statics (Continued...)
Link	NOC:Fluid Flow Operations	Lecture 5 - Fundamentals of flow - Part 1
Link	NOC:Fluid Flow Operations	Lecture 6 - Fundamentals of flow - Part 2
Link	NOC:Fluid Flow Operations	Lecture 7 - One dimensional flow - Part 1
Link	NOC:Fluid Flow Operations	Lecture 8 - One dimensional flow - Part 2
Link	NOC:Fluid Flow Operations	Lecture 9 - One dimensional flow - Part 3
Link	NOC:Fluid Flow Operations	Lecture 10 - Flow of Viscous fluid - Introduction
Link	NOC:Fluid Flow Operations	Lecture 11 - Velocity distribution in laminar flow
Link	NOC:Fluid Flow Operations	Lecture 12 - Velocity distribution in turbulent flow
Link	NOC:Fluid Flow Operations	Lecture 13 - Boundary layer theory
Link	NOC:Fluid Flow Operations	Lecture 14 - Theory of lubrication
Link	NOC:Fluid Flow Operations	Lecture 15 - Frictional resistance
Link	NOC:Fluid Flow Operations	Lecture 16 - Losses in gematric change
Link	NOC:Fluid Flow Operations	Lecture 17 - Losses in geometric change (Continued...)
Link	NOC:Fluid Flow Operations	Lecture 18 - Flow Velocity and Optimum Shape
Link	NOC:Fluid Flow Operations	Lecture 19 - Equation of Energy and Discharge of Water Channel
Link	NOC:Fluid Flow Operations	Lecture 20 - Drag
Link	NOC:Fluid Flow Operations	Lecture 21 - Lift and Cavitation
Link	NOC:Fluid Flow Operations	Lecture 22 - Dimensional Analysis
Link	NOC:Fluid Flow Operations	Lecture 23 - Dimensional Analysis: Buckinghamâ€™s PI Theorem
Link	NOC:Fluid Flow Operations	Lecture 24 - Law of Similarity and Significant Dimensionless Number
Link	NOC:Fluid Flow Operations	Lecture 25 - Compressible Flow - Part 1
Link	NOC:Fluid Flow Operations	Lecture 26 - Compressible Flow - Part 2
Link	NOC:Fluid Flow Operations	Lecture 27 - Measurement of Flow - Part 1
Link	NOC:Fluid Flow Operations	Lecture 28 - Measurement of Flow - Part 2
Link	NOC:Fluid Flow Operations	Lecture 29 - Measurement of Flow - Part 3
Link	NOC:Fluid Flow Operations	Lecture 30 - Introduction to multiphase flow
Link	NOC:Fluid Flow Operations	Lecture 31 - Hydrodynamics in multiphase flow
Link	NOC:Fluid Flow Operations	Lecture 32 - Hydrodynamics in multiphase flow (Continued...)
Link	NOC:Fluid Flow Operations	Lecture 33 - Applications of multiphase flow
Link	NOC:Chemical Process Intensification	Lecture 1 - History, Philosophy and Concept
Link	NOC:Chemical Process Intensification	Lecture 2 - Principle Features
Link	NOC:Chemical Process Intensification	Lecture 3 - Strategies and domain based techniques
Link	NOC:Chemical Process Intensification	Lecture 4 - Intensification by fluid flow process
Link	NOC:Chemical Process Intensification	Lecture 5 - Mechanism of Intensification by mixing
Link	NOC:Chemical Process Intensification	Lecture 6 - Intensification in Reactive system
Link	NOC:Chemical Process Intensification	Lecture 7 - Problems leading to sustainable development
Link	NOC:Chemical Process Intensification	Lecture 8 - Concept, Issues and Challenges
Link	NOC:Chemical Process Intensification	Lecture 9 - Strategies in process design
Link	NOC:Chemical Process Intensification	Lecture 10 - Scales and stages of process intensification
Link	NOC:Chemical Process Intensification	Lecture 11 - Methods and Tools for Achieving sustainable design
Link	NOC:Chemical Process Intensification	Lecture 12 - Multi-level Computer aided tools
Link	NOC:Chemical Process Intensification	Lecture 13 - Introduction on Stochastic Optimization
Link	NOC:Chemical Process Intensification	Lecture 14 - Optimization Algorithms
Link	NOC:Chemical Process Intensification	Lecture 15 - Applications of Optimization Algorithms
Link	NOC:Chemical Process Intensification	Lecture 16 - Introduction and Mechanism of Cavitation-based PI
Link	NOC:Chemical Process Intensification	Lecture 17 - Cavitational Reactor Configurations and activity
Link	NOC:Chemical Process Intensification	Lecture 18 - Parametric effects on cavitation
Link	NOC:Chemical Process Intensification	Lecture 19 - Introduction of monolith reactor
Link	NOC:Chemical Process Intensification	Lecture 20 - Preparation of monolithic catalyst
Link	NOC:Chemical Process Intensification	Lecture 21 - Application of monolithic catalyst
Link	NOC:Chemical Process Intensification	Lecture 22 - Hydrodynamics, transport of monolithic reactor
Link	NOC:Chemical Process Intensification	Lecture 23 - Overview of interfacial area based processes
Link	NOC:Chemical Process Intensification	Lecture 24 - Ejector induced downflow system for PI
Link	NOC:Chemical Process Intensification	Lecture 25 - Hydrodynamics and transport in downflow system
Link	NOC:Chemical Process Intensification	Lecture 26 - Introduction and Principles
Link	NOC:Chemical Process Intensification	Lecture 27 - Types of Intensified Distillation Units
Link	NOC:Chemical Process Intensification	Lecture 28 - Design of membrane-assisted distillation
Link	NOC:Chemical Process Intensification	Lecture 29 - Introduction and Principles
Link	NOC:Chemical Process Intensification	Lecture 30 - Supercritical extraction for process intensification
Link	NOC:Chemical Process Intensification	Lecture 31 - Introduction to membrane and its principles
Link	NOC:Chemical Process Intensification	Lecture 32 - Membrane engineering in process intensification
Link	NOC:Chemical Process Intensification	Lecture 33 - Introduction to microprocess technology
Link	NOC:Chemical Process Intensification	Lecture 34 - Process Intensification by Microreactors
Link	NOC:Chemical Process Intensification	Lecture 35 - Hydrodynamics and transport in microchannel based microreactor
Link	NOC:Chemical Reaction Engineering-I	Lecture 1 - Introduction and Overview on Reaction Engineering
Link	NOC:Chemical Reaction Engineering-I	Lecture 2 - Kinetics of Homogeneous Reactions
Link	NOC:Chemical Reaction Engineering-I	Lecture 3 - Kinetic Model and Temperature Dependency
Link	NOC:Chemical Reaction Engineering-I	Lecture 4 - Introduction and Stoichiometry for the Batch System
Link	NOC:Chemical Reaction Engineering-I	Lecture 5 - Stoichiometry for Constant Volume Flow and Variable Volume Batch Systems
Link	NOC:Chemical Reaction Engineering-I	Lecture 6 - Stoichiometry for Variable Volume Flow System
Link	NOC:Chemical Reaction Engineering-I	Lecture 7 - Analysis of Batch Reactor Kinetic Data
Link	NOC:Chemical Reaction Engineering-I	Lecture 8 - Intregal Method of Analysis of Batch Reactor Data - Part 1
Link	NOC:Chemical Reaction Engineering-I	Lecture 9 - Intregal Method of Analysis of Batch Reactor Data - Part 2
Link	NOC:Chemical Reaction Engineering-I	Lecture 10 - Differential Method of Analysis and Variable Volume Batch Reactor Data
Link	NOC:Chemical Reaction Engineering-I	Lecture 11 - Introduction and Ideal Batch Reactor Design
Link	NOC:Chemical Reaction Engineering-I	Lecture 12 - Ideal Mixed Flow Reactor Design
Link	NOC:Chemical Reaction Engineering-I	Lecture 13 - Ideal Plug Flow Reactor Design
Link	NOC:Chemical Reaction Engineering-I	Lecture 14 - Size Comparisn of Single and Multiple Reactors
Link	NOC:Chemical Reaction Engineering-I	Lecture 15 - Size Comaprison Multiple Reactors
Link	NOC:Chemical Reaction Engineering-I	Lecture 16 - Recycle and Autocatalytic Reactors
Link	NOC:Chemical Reaction Engineering-I	Lecture 17 - Design for Parallel Reactions
Link	NOC:Chemical Reaction Engineering-I	Lecture 18 - Design for Series Reactions
Link	NOC:Chemical Reaction Engineering-I	Lecture 19 - Design for Series-Parallel Reactions
Link	NOC:Chemical Reaction Engineering-I	Lecture 20 - Denbigh Reactions and Their Special Cases
Link	NOC:Chemical Reaction Engineering-I	Lecture 21 - Heats of Reaction and Equilibrium Conversion from Thermodynamics
Link	NOC:Chemical Reaction Engineering-I	Lecture 22 - General Graphical Reactor Design Procedure
Link	NOC:Chemical Reaction Engineering-I	Lecture 23 - Material and Energy Balances in Batch Reactor
Link	NOC:Chemical Reaction Engineering-I	Lecture 24 - Optimum Temperature Progression in Batch Reactor
Link	NOC:Chemical Reaction Engineering-I	Lecture 25 - Material and Energy Balances in Flug Flow and Mixed Flow Reactors
Link	NOC:Chemical Reaction Engineering-I	Lecture 26 - Ideal and Non-Ideal Mixed Flow Reactor Design and Multiple Steady States
Link	NOC:Chemical Reaction Engineering-I	Lecture 27 - Non-Ideal Reactors and Residence Time Distribution
Link	NOC:Chemical Reaction Engineering-I	Lecture 28 - RTD Measurement and Moments of RTD
Link	NOC:Chemical Reaction Engineering-I	Lecture 29 - RTD in Ideal Reactors
Link	NOC:Chemical Reaction Engineering-I	Lecture 30 - Reactor Modeling using the RTD
Link	NOC:Mass Transfer Operations-II	Lecture 1 - Basic concepts, Adiabatic saturation temperature
Link	NOC:Mass Transfer Operations-II	Lecture 2 - Design calculations of cooling tower
Link	NOC:Mass Transfer Operations-II	Lecture 3 - Design of cooling tower
Link	NOC:Mass Transfer Operations-II	Lecture 4 - Design of cooling tower
Link	NOC:Mass Transfer Operations-II	Lecture 5 - Air conditioning, Example problems on dehumidification
Link	NOC:Mass Transfer Operations-II	Lecture 6 - Mechanism of drying and drying equilibria, drying rate curve
Link	NOC:Mass Transfer Operations-II	Lecture 7 - Drying: rate of drying for batch dryers
Link	NOC:Mass Transfer Operations-II	Lecture 8 - Drying: rate of drying for continuous dryers
Link	NOC:Mass Transfer Operations-II	Lecture 9 - Drying time calculation from drying rate curve
Link	NOC:Mass Transfer Operations-II	Lecture 10 - Introduction to liquid-liquid extraction, liquid-liquid equilibria
Link	NOC:Mass Transfer Operations-II	Lecture 11 - Effect of temperature on LLE and Design of single stage extraction
Link	NOC:Mass Transfer Operations-II	Lecture 12 - Design Calculation of Multistage Operation
Link	NOC:Mass Transfer Operations-II	Lecture 13 - Design calculation of multistage cross-current extraction
Link	NOC:Mass Transfer Operations-II	Lecture 14 - Design calculation of multistage counter-current extraction, Selection of extractors
Link	NOC:Mass Transfer Operations-II	Lecture 15 - Leaching: single stage operation
Link	NOC:Mass Transfer Operations-II	Lecture 16 - Leaching: multistage operation
Link	NOC:Mass Transfer Operations-II	Lecture 17 - Supercritical Fluid Extraction, equipmet for leaching
Link	NOC:Mass Transfer Operations-II	Lecture 18 - Fundamentals of membrane separation processes
Link	NOC:Mass Transfer Operations-II	Lecture 19 - Manufacturing of membranes,advantages and limitations
Link	NOC:Mass Transfer Operations-II	Lecture 20 - Various models and applications: design aspects
Link	NOC:Mass Transfer Operations-II	Lecture 21 - Various models and applications: design aspects
Link	NOC:Mass Transfer Operations-II	Lecture 22 - Electric field enhanced membrane separation processes
Link	NOC:Mass Transfer Operations-II	Lecture 23 - Micellar-enhanced ultrafiltration
Link	NOC:Mass Transfer Operations-II	Lecture 24 - Adsorption: types and nature, isotherm
Link	NOC:Mass Transfer Operations-II	Lecture 25 - Stage wise and continuous adsorption
Link	NOC:Mass Transfer Operations-II	Lecture 26 - Fluidized bed and teeter bed
Link	NOC:Mass Transfer Operations-II	Lecture 27 - Unsteady state fixed bed adsorbers, ion exchange
Link	NOC:Mass Transfer Operations-II	Lecture 28 - Crystallization, types of crystal geometry
Link	NOC:Mass Transfer Operations-II	Lecture 29 - Solid-liquid phase equilibrium, Theory of crystallization
Link	NOC:Mass Transfer Operations-II	Lecture 30 - Design of crystallizer, crystallization equipment
Link	NOC:Mass Transfer Operations-II	Lecture 31 - Concluding remarks - Part 1
Link	NOC:Mass Transfer Operations-II	Lecture 32 - Concluding remarks - Part 2
Link	NOC:Mechanical Unit Operations	Lecture 1 - Introduction of Particulate Solids
Link	NOC:Mechanical Unit Operations	Lecture 2 - Particle Size
Link	NOC:Mechanical Unit Operations	Lecture 3 - Particle Shape and Density
Link	NOC:Mechanical Unit Operations	Lecture 4 - Screening
Link	NOC:Mechanical Unit Operations	Lecture 5 - Size Analysis by Screening
Link	NOC:Mechanical Unit Operations	Lecture 6 - Screening Equipment, Effectiveness and Capacity
Link	NOC:Mechanical Unit Operations	Lecture 7 - Methods of Size Reduction
Link	NOC:Mechanical Unit Operations	Lecture 8 - Equipment for Size Reduction - Crushers
Link	NOC:Mechanical Unit Operations	Lecture 9 - Equipment for Size Reduction - Gridners
Link	NOC:Mechanical Unit Operations	Lecture 10 - Equipment for Size Reduction - Ultrafine Grinders and Cutting Machines
Link	NOC:Mechanical Unit Operations	Lecture 11 - Storage of Bulk Solids
Link	NOC:Mechanical Unit Operations	Lecture 12 - Solids Flow Out and their Flow Patterns
Link	NOC:Mechanical Unit Operations	Lecture 13 - Conveying of Bulk Solids
Link	NOC:Mechanical Unit Operations	Lecture 14 - Size Enlargement Methods
Link	NOC:Mechanical Unit Operations	Lecture 15 - Size Enlargement Equipment - 1
Link	NOC:Mechanical Unit Operations	Lecture 16 - Size Enlargement Equipment - 2
Link	NOC:Mechanical Unit Operations	Lecture 17 - Flow past Immersed Solid Objects
Link	NOC:Mechanical Unit Operations	Lecture 18 - Motion of Particles through Fluids - 1
Link	NOC:Mechanical Unit Operations	Lecture 19 - Motion of Particles through Fluids - 2
Link	NOC:Mechanical Unit Operations	Lecture 20 - Motion of Particles through Fluids - 3
Link	NOC:Mechanical Unit Operations	Lecture 21 - Flow through Beds of Solids - 1
Link	NOC:Mechanical Unit Operations	Lecture 22 - Flow through Beds of Solids - 2
Link	NOC:Mechanical Unit Operations	Lecture 23 - Flow through Fluidized Beds - 1
Link	NOC:Mechanical Unit Operations	Lecture 24 - Flow through Fluidized Beds - 2
Link	NOC:Mechanical Unit Operations	Lecture 25 - Filtration
Link	NOC:Mechanical Unit Operations	Lecture 26 - Principles of Cake Filtration - 1
Link	NOC:Mechanical Unit Operations	Lecture 27 - Principles of Cake Filtration - 2
Link	NOC:Mechanical Unit Operations	Lecture 28 - Filtration Equipment
Link	NOC:Mechanical Unit Operations	Lecture 29 - Cross Flow Filtration - 1
Link	NOC:Mechanical Unit Operations	Lecture 30 - Cross Flow Filtration - 2
Link	NOC:Mechanical Unit Operations	Lecture 31 - Gravity Sedimentation - Classifiers
Link	NOC:Mechanical Unit Operations	Lecture 32 - Gravity Sedimentation - Design of Thickeners - 1
Link	NOC:Mechanical Unit Operations	Lecture 33 - Gravity Sedimentation - Design of Thickeners - 2
Link	NOC:Mechanical Unit Operations	Lecture 34 - Centrifugal Separations - 1
Link	NOC:Mechanical Unit Operations	Lecture 35 - Centrifugal Separations - 2
Link	NOC:Mechanical Unit Operations	Lecture 36 - Floatation - 1
Link	NOC:Mechanical Unit Operations	Lecture 37 - Floatation - 2
Link	NOC:Advanced Thermodynamics	Lecture 1 - Introduction of Phase Equilibrium
Link	NOC:Advanced Thermodynamics	Lecture 2 - Classical Thermodynamics of Phase Equilibria - 1
Link	NOC:Advanced Thermodynamics	Lecture 3 - Classical Thermodynamics of Phase Equilibria - 2
Link	NOC:Advanced Thermodynamics	Lecture 4 - Thermodynamic Properties from Volumetric Data
Link	NOC:Advanced Thermodynamics	Lecture 5 - Fugacity from Volumetric Data - 1
Link	NOC:Advanced Thermodynamics	Lecture 6 - Fugacity from Volumetric Data - 2
Link	NOC:Advanced Thermodynamics	Lecture 7 - Intermolecular Forces and Non-Ideal Behaviour
Link	NOC:Advanced Thermodynamics	Lecture 8 - Intermolecular Forces-Potential Energy Functions
Link	NOC:Advanced Thermodynamics	Lecture 9 - Molecular Theory of Corresponding States - 1
Link	NOC:Advanced Thermodynamics	Lecture 10 - Molecular Theory of Corresponding States - 2
Link	NOC:Advanced Thermodynamics	Lecture 11 - Intermolecular Potential and EoS
Link	NOC:Advanced Thermodynamics	Lecture 12 - Virial Coefficients from Potential Functions
Link	NOC:Advanced Thermodynamics	Lecture 13 - Virial Coefficients from Corresponding States Theory
Link	NOC:Advanced Thermodynamics	Lecture 14 - Fugacities in Gaseous Mixtures - 1
Link	NOC:Advanced Thermodynamics	Lecture 15 - Fugacities in Gaseous Mixtures - 2
Link	NOC:Advanced Thermodynamics	Lecture 16 - Fugacities in Gaseous Mixtures - 3
Link	NOC:Advanced Thermodynamics	Lecture 17 - Liquid Mixtures and Excess Functions
Link	NOC:Advanced Thermodynamics	Lecture 18 - Excess Functions and Activity Coefficients
Link	NOC:Advanced Thermodynamics	Lecture 19 - Activity Coefficients and Thermodynamic Consistency
Link	NOC:Advanced Thermodynamics	Lecture 20 - Models for Excess Gibbs Energy - 1
Link	NOC:Advanced Thermodynamics	Lecture 21 - Models for Excess Gibbs Energy - 2
Link	NOC:Advanced Thermodynamics	Lecture 22 - Models for Excess Gibbs Energy - 3
Link	NOC:Advanced Thermodynamics	Lecture 23 - Vapour-Liquid Equilibrium - 1
Link	NOC:Advanced Thermodynamics	Lecture 24 - Vapour-Liquid Equilibrium - 2
Link	NOC:Advanced Thermodynamics	Lecture 25 - Vapour-Liquid Equilibrium - 3
Link	NOC:Advanced Thermodynamics	Lecture 26 - Liquid-Liquid Equilibrium - 1
Link	NOC:Advanced Thermodynamics	Lecture 27 - Liquid-Liquid Equilibrium - 2
Link	NOC:Advanced Thermodynamics	Lecture 28 - Vapour-Liquid-Liquid Equilibrium - 1
Link	NOC:Advanced Thermodynamics	Lecture 29 - Vapour-Liquid-Liquid Equilibrium - 2
Link	NOC:Advanced Thermodynamics	Lecture 30 - Solid-Liquid Equilibrium - 1
Link	NOC:Advanced Thermodynamics	Lecture 31 - Solid-Liquid Equilibrium - 2
Link	NOC:Membrane Technology	Lecture 1 - Separation Processes, Historical Development, Definition and Types of Membranes
Link	NOC:Membrane Technology	Lecture 2 - Membrane Processes and Classifications, Advantages, Disadvantages, Applications
Link	NOC:Membrane Technology	Lecture 3 - Polymer Basics, Polymers used in Membrane Preparation and their Properties
Link	NOC:Membrane Technology	Lecture 4 - Inorganic Materials for Membrane Preparation, their Advantages and Disadvantages
Link	NOC:Membrane Technology	Lecture 5 - Membrane Modules and Selection, Flow Types
Link	NOC:Membrane Technology	Lecture 6 - Preparation of Synthetic Membrane, Phase Inversion Membranes
Link	NOC:Membrane Technology	Lecture 7 - Composite membranes: Interfacial polymerization, dip-coating, plasma polymerization
Link	NOC:Membrane Technology	Lecture 8 - Inorganic membranes: Sol-Gel process, ceramic membrane preparation, membrane modification
Link	NOC:Membrane Technology	Lecture 9 - Porous and non-porous membranes, characterization of porous membranes and MF membrane
Link	NOC:Membrane Technology	Lecture 10 - MF membrane characterization: Bubble point,Mercury intrusion, Permeability method
Link	NOC:Membrane Technology	Lecture 11 - UF membrane characterization: Gas adsorption-desorption, Thermoporometry, MWCO method
Link	NOC:Membrane Technology	Lecture 12 - Passive transport, active transport, description of transport process
Link	NOC:Membrane Technology	Lecture 13 - Transport through porous membrane and nonporus membrane
Link	NOC:Membrane Technology	Lecture 14 - Concept of osmosis and reverse osmosis, thermodynamic analysis
Link	NOC:Membrane Technology	Lecture 15 - Revision of concepts and fundaments
Link	NOC:Membrane Technology	Lecture 16 - HP and LP RO, membrane materials, modules, models for RO transport
Link	NOC:Membrane Technology	Lecture 17 - Advantages of RO, fouling, RO applications, Pressure retarded osmosis
Link	NOC:Membrane Technology	Lecture 18 - Nanofiltration basics, transport mechanism, fouling model and applications
Link	NOC:Membrane Technology	Lecture 19 - Basic principles of UF, membranes and modules, UF configurations
Link	NOC:Membrane Technology	Lecture 20 - Models for UF transport, mass transfer coefficient, membrane rejection and sieving coefficient
Link	NOC:Membrane Technology	Lecture 21 - Factors affecting UF performance, fouling and permeate flux enhancement, UF applications1
Link	NOC:Membrane Technology	Lecture 22 - Micellar-enhanced UF, affinity UF, UF based bioseparation
Link	NOC:Membrane Technology	Lecture 23 - Basic principles, advantages of MF, cross-flow and dead-end MF, membranes and modules
Link	NOC:Membrane Technology	Lecture 24 - Models for MF transport, plugging and throughput, fouling in MF, MF applications
Link	NOC:Membrane Technology	Lecture 25 - Problems and solutions based on RO and MF
Link	NOC:Membrane Technology	Lecture 26 - Problems and solutions based on UF
Link	NOC:Membrane Technology	Lecture 27 - Dialysis, membranes and modules, mass transport in dialysis, diffusion analysis, applications
Link	NOC:Membrane Technology	Lecture 28 - Ion-exchange membranes, ED process, energy requirement, applications, reverse ED
Link	NOC:Membrane Technology	Lecture 29 - PV principle, advantages, mass transfer and applications, hybrid distillation/PV
Link	NOC:Membrane Technology	Lecture 30 - Problems and solutions based on ED and PV
Link	NOC:Membrane Technology	Lecture 31 - Concept, types of LM, mechanism of mass transfer in LM, choice of solvent and carrier, applications
Link	NOC:Membrane Technology	Lecture 32 - Basic principle of gas separation, transport mechanism, factors affecting gas separation, applications
Link	NOC:Membrane Technology	Lecture 33 - Basic principle of MD, mechanism, process parameters, membranes, applications
Link	NOC:Membrane Technology	Lecture 34 - Mechanism, coupled transport, carrier agent, active and passive transport, applications
Link	NOC:Membrane Technology	Lecture 35 - Gas-liquid and liquid-liquid contactors, membrane reactors and bioreactors, PEM hydrogen fuel cell
Link	NOC:Membrane Technology	Lecture 36 - Perstraction, membrane chromatography and controlled drug delivery
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 1 - Introduction to Optimization
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 2 - Linear Regression
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 3 - Multiple, Polynomial and General Linear Least Square Regression
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 4 - Nonlinear Regression
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 5 - Regression : MATLAB Implementation
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 6 - Teaching Learning Based Optimization
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 7 - Implementation of TLBO in MATLAB
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 8 - Supplementary: Preliminary Statistical analysis for metaheuristic techniques
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 9 - Supplementary: Preliminary Statistical analysis - MATLAB implementation
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 10 - Particle Swarm Optimization
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 11 - Implementation of Particle Swarm Optimization using MATLAB
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 12 - Differential Evolution
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 13 - Implementation of Differential Evolution using MATLAB
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 14 - Binary Coded Genetic Algorithm
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 15 - Real Coded Genetic Algorithm
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 16 - Implementation of Real Coded Genetic Algorithm using MATLAB
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 17 - Artificial Bee Colony Algorithm
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 18 - Working of Artificial Bee Colony Algorithm
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 19 - Implementation of Artificial Bee Colony using MATLAB
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 20 - Comparison of Variation Operators and Survival Strategies
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 21 - Black-Box Optimization Problems
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 22 - Constraint-Handling in Metaheuristic Techniques
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 23 - Case Study: Production planning
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 24 - Case Study: Production planning MATLAB Implementation
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 25 - Parallelization and Vectorization of Fitness Function
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 26 - Constraint-Handling using Correction Approach
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 27 - MATLAB inbuilt functions: Linear and Mixed Integer Linear Programming
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 28 - MATLAB inbuilt functions: Nonlinear and Mixed Integer Nonlinear Programming
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 29 - MATLAB Optimization Tool: Options, Output Function, Vectorization, Parallelization
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 30 - MATLAB inbuilt functions: Multi-objective Optimization
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 31 - Simplex Method for LP
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 32 - Branch and Bound Method for MILP
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 33 - MILP formulation of Production Planning Problem
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 34 - Generalized Algebraic Modelling System
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 35 - Solution of Production Planning Problem using GAMS and NEOS, MIRO
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 36 - IBM ILOG CPLEX Optimization Studio
Link	NOC:Computer Aided Applied Single Objective Optimization	Lecture 37 - Constraint Programming Applications in IBM ILOG CPLEX Optimization Studio
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 1 - Definition, History, Role of Chemical Engineer
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 2 - Basic Features of Chemical Process
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 3 - Unit systems and dimensions
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 4 - Variables and Properties of Material in System
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 5 - Pressure and Temperature of Flow Process
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 6 - Rate of Process
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 7 - Principles of material balance and calculation
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 8 - Material Balances on Processes with Recycle and Bypass
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 9 - Material balances on reactive processes
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 10 - Material balances on combustion reactions
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 11 - State Equation of Ideal Gas and Calculation
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 12 - State Equation of non-Ideal Gas and Calculation
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 13 - Phase equilibrium
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 14 - Equilibrium Laws, Humidity and Saturation
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 15 - Humidity, Saturation Psychrometric chart
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 16 - Process of phase change: Condensation and vaporization
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 17 - Principles of Energy
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 18 - Laws and properties of thermodynamics
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 19 - Standard Heat of Formation
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 20 - The mechanical energy balance
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 21 - Enthalpy balances without reaction
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 22 - Energy balance with multiplle streams without reaction
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 23 - Energy balance on heat of solution
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 24 - Energy balance with heat of reaction
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 25 - Energy balance with heat of reaction (Continued...)
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 26 - Energy balance with heat of combustion
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 27 - Material balance of transient process
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 28 - Unsteady state energy balance
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 29 - Least Square Method Linear equation fitting
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 30 - Non-linear algebraic equation system
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 31 - Numerical Integration
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 32 - Process Degrees of Freedom
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 33 - Process Flowsheeting and codes
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 34 - Case Study: Cumene Production
Link	NOC:Basic Principles and Calculations in Chemical Engineering	Lecture 35 - Case Study: Cumene Production (Continued...)
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 1 - Solar Energy: An overview of thermal applications
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 2 - Solar radiation
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 3 - Practice problems - Part I
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 4 - Practice problems - Part II
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 5 - Non-concentrating solar collectors - Part I
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 6 - Non-concentrating solar collectors - Part II
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 7 - Non-concentrating solar collectors - Part III
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 8 - Practice problems - Part I
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 9 - Practice problems - Part II
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 10 - Practice problems - Part III
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 11 - Parabolic solar collectors
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 12 - Practice problems
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 13 - Thermal energy storage systems - Part I
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 14 - Thermal energy storage systems - Part II
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 15 - Solar energy utilization methods
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 16 - Classification of energy resources
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 17 - Broad classification and compositional analysis
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 18 - Characteristics and properties of biomass
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 19 - Properties and structural components of biomass
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 20 - Biomass residues and energy conversion routes
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 21 - Utilisation of biomass through bio-chemical and thermo-chemical routes
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 22 - Conversion mechanism of biomass to biogas and its properties
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 23 - Classification of biogas plants
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 24 - Practice problems - I
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 25 - Practice problems - II
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 26 - Practice problems - III
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 27 - Bioconversion of substrates into alcohol
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 28 - Thermo-chemical conversion, torrefaction and combustion processes
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 29 - Thermo-chemical conversion of biomass to solid, liquid and gaseous fuels
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 30 - Gasification process
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 31 - Thermo-chemical conversion processes: pyrolysis, liquefaction and conversion processes
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 32 - Practice problems - I
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 33 - Practice problems - II
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 34 - Turbine terms, types and theories - Part I
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 35 - Turbine terms, types and theories - Part II
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 36 - Characteristics and Power Generation from Wind Energy - Part I
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 37 - Characteristics and Power Generation from Wind Energy - Part II
Link	NOC:Renewable Energy Engineering: Solar, Wind and Biomass Energy Systems	Lecture 38 - Practice problems
Link	NOC:Biomass Conversion and Biorefinery	Lecture 1 - Energy and Environment scenario
Link	NOC:Biomass Conversion and Biorefinery	Lecture 2 - Need for biomass based industries
Link	NOC:Biomass Conversion and Biorefinery	Lecture 3 - Biomass basics
Link	NOC:Biomass Conversion and Biorefinery	Lecture 4 - Dedicated energy crops
Link	NOC:Biomass Conversion and Biorefinery	Lecture 5 - Oil cropns and microalgae
Link	NOC:Biomass Conversion and Biorefinery	Lecture 6 - Enhancing biomass properties
Link	NOC:Biomass Conversion and Biorefinery	Lecture 7 - Basic concepts and types
Link	NOC:Biomass Conversion and Biorefinery	Lecture 8 - Feedstocks and properties
Link	NOC:Biomass Conversion and Biorefinery	Lecture 9 - Economics and LCA
Link	NOC:Biomass Conversion and Biorefinery	Lecture 10 - Barriers and Types
Link	NOC:Biomass Conversion and Biorefinery	Lecture 11 - Dilute acid, alkali, ozone
Link	NOC:Biomass Conversion and Biorefinery	Lecture 12 - Hybrid methods
Link	NOC:Biomass Conversion and Biorefinery	Lecture 13 - Physical Processes
Link	NOC:Biomass Conversion and Biorefinery	Lecture 14 - Gasification and Pyrolysis
Link	NOC:Biomass Conversion and Biorefinery	Lecture 15 - Products and Commercial Success Stories
Link	NOC:Biomass Conversion and Biorefinery	Lecture 16 - Types, fundamentals, equipments, applications
Link	NOC:Biomass Conversion and Biorefinery	Lecture 17 - Details of various processes
Link	NOC:Biomass Conversion and Biorefinery	Lecture 18 - Products and Commercial Success Stories
Link	NOC:Biomass Conversion and Biorefinery	Lecture 19 - Diesel from vegetable oils, microalgae and syngas
Link	NOC:Biomass Conversion and Biorefinery	Lecture 20 - Transesterification; FT process, catalysts
Link	NOC:Biomass Conversion and Biorefinery	Lecture 21 - Biodiesel purification, fuel properties
Link	NOC:Biomass Conversion and Biorefinery	Lecture 22 - Biooil and biochar production, reactors
Link	NOC:Biomass Conversion and Biorefinery	Lecture 23 - Factors affecting biooil, biochar production, fuel properties characterization
Link	NOC:Biomass Conversion and Biorefinery	Lecture 24 - Biooil upgradation technologies
Link	NOC:Biomass Conversion and Biorefinery	Lecture 25 - Microorganisms, current industrial ethanol production technology
Link	NOC:Biomass Conversion and Biorefinery	Lecture 26 - Cellulase production, SSF and CBP
Link	NOC:Biomass Conversion and Biorefinery	Lecture 27 - ABE fermentation pathway and kinetics, product recovery technologies
Link	NOC:Biomass Conversion and Biorefinery	Lecture 28 - Biohydrogen production, metabolics, microorganisms
Link	NOC:Biomass Conversion and Biorefinery	Lecture 29 - Biogas technology, fermenter designs, biogas purification
Link	NOC:Biomass Conversion and Biorefinery	Lecture 30 - Methanol production and utilization
Link	NOC:Biomass Conversion and Biorefinery	Lecture 31 - Biomass as feedstock for synthetic organic chemicals, lactic acid, polylactic acid
Link	NOC:Biomass Conversion and Biorefinery	Lecture 32 - Succinic acid, propionic acid, acetic acid, butyric acid
Link	NOC:Biomass Conversion and Biorefinery	Lecture 33 - 1,3-propanediol, 2,3-butanedioil, PHA
Link	NOC:Biomass Conversion and Biorefinery	Lecture 34 - Concept, lignocellulosic biorefinery
Link	NOC:Biomass Conversion and Biorefinery	Lecture 35 - Aquaculture and algal biorefinery, waste biorefinery
Link	NOC:Biomass Conversion and Biorefinery	Lecture 36 - Techno-economic evaluation
Link	NOC:Biomass Conversion and Biorefinery	Lecture 37 - Life-cycle assessment
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 1 - Significance of software with example - Simulation on pen and paper vs simulation on Aspen Plus
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 2 - Understanding Resources and My Exchange, Start using Aspen Plus
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 3 - Overview of setting up of property environment
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 4 - Using Model Pallete - Mixers/Splitters, Separators
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 5 - Using Model Pallete - Exchangers
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 6 - Using Model Pallete - Columns
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 7 - Using Model Palette - Reactors
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 8 - Using Model Palette - Pressure Changers
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 9 - Example: Hydrocarbon Treatment - Part 1
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 10 - Example: Hydrocarbon Treatment - Part 2
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 11 - Setup, Components
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 12 - Property Methods
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 13 - Property Methods and Propeety Sets with example
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 14 - Analysis tools (Pure Components and Binary mixtures)
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 15 - Analysis tools (Ternary mixtures), Data and Regression (Part 1)
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 16 - Data and Regression (Part 2), Property Estimation
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 17 - Practice problems on pure components
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 18 - Practice problems on binary mixtures
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 19 - Miscellaneous practice problems and case studies
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 20 - Model Analysis Tools
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 21 - Separation of Hydrocarbon Mixture
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 22 - Synthesis of Acetaldehyde from Ethanol
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 23 - BTX Separation through Distillation
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 24 - Synthesis of Methanol from Syngas
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 25 - Synthesis of Dimethyl Ether from Carbon Dioxide and Hydrogen
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 26 - Synthesis of Ammonia in Cryogenic Process
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 27 - Production of Cumene
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 28 - Design, Rating and Simulation of Heat Exchanger
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 29 - Absorption and Distillation - Part 1
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 30 - Absorption and Distillation - Part 2
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 31 - Hydrodealkylation of Toluene
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 32 - Isobutene Production Plant
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 33 - Nitric Oxide Production Plant
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 34 - Plant Economy and Utilities
Link	NOC:Aspen Plus® Simulation Software - A basic course for beginners	Lecture 35 - Plant Dynamics and Control
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 1 - Introduction of Characterization Techniques - Part 1
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 2 - Introduction to Characterization Techniques - Part 2
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 3 - Infrared Spectroscopy: Fundamentals
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 4 - Infrared Spectroscopy: IR Bands and Applications
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 5 - Infrared Spectrophotometer Instrumentation
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 6 - Raman Spectroscopy
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 7 - NMR: Concepts and Fundamentals
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 8 - Chemical Shifts
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 9 - Factors Affecting Chemical Shift and 2D NMR
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 10 - Physisorption: Surface Area and Pore Analysis
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 11 - Physisorption Measurements
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 12 - Chemisorption
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 13 - Surface Tension and its Measurement - Part 1
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 14 - Surface Tension and its Measurement - Part 2
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 15 - Interfacial Tension and its Application
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 16 - Interfacial Tension and Influence of Surface Curvature
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 17 - Rheology: Fundamentals and Principles
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 18 - Complex Fluids and their Properties
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 19 - Rheology: Case Study on Hydrogel Synthesis
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 20 - Electron Spectroscopy for Surface Analysis
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 21 - Quantification in XRF and XPS Spectroscopy
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 22 - XPS Instrument and Application
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 23 - Introduction to Electrochemical Characterization Techniques
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 24 - Electrode Potential, Kinetics and Mass Transfer Resistance
Link	NOC:Physical and Electrochemical Characterizations in Chemical Engineering	Lecture 25 - Voltammetry and Galvanostatic Charge-Discharge
Link	Fluid Mechanics	Lecture 1
Link	Fluid Mechanics	Lecture 2
Link	Fluid Mechanics	Lecture 3
Link	Fluid Mechanics	Lecture 4
Link	Fluid Mechanics	Lecture 5
Link	Fluid Mechanics	Lecture 6
Link	Fluid Mechanics	Lecture 7
Link	Fluid Mechanics	Lecture 8
Link	Fluid Mechanics	Lecture 9
Link	Fluid Mechanics	Lecture 10
Link	Fluid Mechanics	Lecture 11
Link	Fluid Mechanics	Lecture 12
Link	Fluid Mechanics	Lecture 13
Link	Fluid Mechanics	Lecture 14
Link	Fluid Mechanics	Lecture 15
Link	Fluid Mechanics	Lecture 16
Link	Fluid Mechanics	Lecture 17
Link	Fluid Mechanics	Lecture 18
Link	Fluid Mechanics	Lecture 19
Link	Fluid Mechanics	Lecture 20
Link	Fluid Mechanics	Lecture 21
Link	Fluid Mechanics	Lecture 22
Link	Fluid Mechanics	Lecture 23
Link	Fluid Mechanics	Lecture 24
Link	Fluid Mechanics	Lecture 25
Link	Fluid Mechanics	Lecture 26
Link	Fluid Mechanics	Lecture 27
Link	Fluid Mechanics	Lecture 28
Link	Fluid Mechanics	Lecture 29
Link	Fluid Mechanics	Lecture 30
Link	Fluid Mechanics	Lecture 31
Link	Fluid Mechanics	Lecture 32
Link	Fluid Mechanics	Lecture 33
Link	Fluid Mechanics	Lecture 34
Link	Fluid Mechanics	Lecture 35
Link	Fluid Mechanics	Lecture 36
Link	Fluid Mechanics	Lecture 37
Link	Fluid Mechanics	Lecture 38
Link	Fluid Mechanics	Lecture 39
Link	Fluid Mechanics	Lecture 40
Link	Mass Transfer II	Lecture 1
Link	Mass Transfer II	Lecture 2
Link	Mass Transfer II	Lecture 3
Link	Mass Transfer II	Lecture 4
Link	Mass Transfer II	Lecture 5
Link	Mass Transfer II	Lecture 6
Link	Mass Transfer II	Lecture 7
Link	Mass Transfer II	Lecture 8
Link	Mass Transfer II	Lecture 9
Link	Mass Transfer II	Lecture 10
Link	Mass Transfer II	Lecture 11
Link	Mass Transfer II	Lecture 12
Link	Mass Transfer II	Lecture 13
Link	Mass Transfer II	Lecture 14
Link	Mass Transfer II	Lecture 15
Link	Mass Transfer II	Lecture 16
Link	Mass Transfer II	Lecture 17
Link	Mass Transfer II	Lecture 18
Link	Mass Transfer II	Lecture 19
Link	Mass Transfer II	Lecture 20
Link	Mass Transfer II	Lecture 21
Link	Mass Transfer II	Lecture 22
Link	Mass Transfer II	Lecture 23
Link	Mass Transfer II	Lecture 24
Link	Mass Transfer II	Lecture 25
Link	Mass Transfer II	Lecture 26
Link	Mass Transfer II	Lecture 27
Link	Mass Transfer II	Lecture 28
Link	Mass Transfer II	Lecture 29
Link	Mass Transfer II	Lecture 30
Link	Mass Transfer II	Lecture 31
Link	Mass Transfer II	Lecture 32
Link	Mass Transfer II	Lecture 33
Link	Mass Transfer II	Lecture 34
Link	Mass Transfer II	Lecture 35
Link	Mass Transfer II	Lecture 36
Link	Mass Transfer II	Lecture 37
Link	Mass Transfer II	Lecture 38
Link	Mass Transfer II	Lecture 39
Link	Mass Transfer II	Lecture 40
Link	Plantwide Control of Chemical Processes	Lecture 1 - Introduction to the course
Link	Plantwide Control of Chemical Processes	Lecture 2 - Process Dynamics and Negative Feedback
Link	Plantwide Control of Chemical Processes	Lecture 3 - PID control
Link	Plantwide Control of Chemical Processes	Lecture 4 - Common Industrial Control Loops and advanced loops
Link	Plantwide Control of Chemical Processes	Lecture 5 - Advanced loops (Continued...) and multivariable systems
Link	Plantwide Control of Chemical Processes	Lecture 6 - Systematic Tuning Using Frequency Domain Analysis
Link	Plantwide Control of Chemical Processes	Lecture 7 - Frequency Domain Analysis
Link	Plantwide Control of Chemical Processes	Lecture 8 - Multivariable Systems
Link	Plantwide Control of Chemical Processes	Lecture 9 - RGA and dynamic decoupling
Link	Plantwide Control of Chemical Processes	Lecture 10 - Model based control
Link	Plantwide Control of Chemical Processes	Lecture 11 - Dynamic Matrix Control
Link	Plantwide Control of Chemical Processes	Lecture 12 - Control of Distillation Columns
Link	Plantwide Control of Chemical Processes	Lecture 13 - Temperature inferential distillation control
Link	Plantwide Control of Chemical Processes	Lecture 14 - Considerations in temperature inferential control
Link	Plantwide Control of Chemical Processes	Lecture 15 - Control of Complex Column Configurations
Link	Plantwide Control of Chemical Processes	Lecture 16 - Control of Heat Integrated Columns
Link	Plantwide Control of Chemical Processes	Lecture 17 - Homogenous extractive distillation
Link	Plantwide Control of Chemical Processes	Lecture 18 - More on complex columns and reactive distillation
Link	Plantwide Control of Chemical Processes	Lecture 19 - Control of reactors
Link	Plantwide Control of Chemical Processes	Lecture 20 - PFR controls (Continued..) & CSTRs
Link	Plantwide Control of Chemical Processes	Lecture 21 - CSTR heat management
Link	Plantwide Control of Chemical Processes	Lecture 22 - Heat Exchangers and Miscellaneous Systems
Link	Plantwide Control of Chemical Processes	Lecture 23 - Degrees of freedom analysis
Link	Plantwide Control of Chemical Processes	Lecture 24 - Degrees of freedom (Continued...)
Link	Plantwide Control of Chemical Processes	Lecture 25 - Illustration of considerations in control structure synthesis
Link	Plantwide Control of Chemical Processes	Lecture 26 - Two column recycle process
Link	Plantwide Control of Chemical Processes	Lecture 27 - Throughput manipulator selection
Link	Plantwide Control of Chemical Processes	Lecture 28 - Plantwide control structure design
Link	Plantwide Control of Chemical Processes	Lecture 29 - Systematizing plantwide control design
Link	Plantwide Control of Chemical Processes	Lecture 30 - The Luyben design procedure
Link	Plantwide Control of Chemical Processes	Lecture 31 - Role of equipment capacity constraints
Link	Plantwide Control of Chemical Processes	Lecture 32 - Recycle process case study
Link	Plantwide Control of Chemical Processes	Lecture 33 - Recycle process case study (Continued...)
Link	Plantwide Control of Chemical Processes	Lecture 34 - C4 isomerization process case study
Link	Plantwide Control of Chemical Processes	Lecture 35 - C4 isomerization process case study (Continued...)
Link	Plantwide Control of Chemical Processes	Lecture 36 - C4 isomerization process case study
Link	Plantwide Control of Chemical Processes	Lecture 37 - Systematic economic plantwide control design procedure
Link	Plantwide Control of Chemical Processes	Lecture 38 - Ethyl benzene process case study
Link	Plantwide Control of Chemical Processes	Lecture 39 - C4 isomerization process revisited
Link	Plantwide Control of Chemical Processes	Lecture 40 - Contrasting conventional and top-down approach
Link	Plantwide Control of Chemical Processes	Lecture 41 - Cumene process plantwide control
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 1 - Review - 1
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 2 - Review - Temperature and Pressure
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 3 - Review - Energy Conservation
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 4 - Properties - Part 1
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 5 - Properties - Part 2
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 6 - Mass-energy analysis of open system
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 7 - Energy analysis of closed system
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 8 - The Second Law of Thermodynamics
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 9 - Entropy
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 10 - Thermodynamic Calculus - 1
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 11 - Thermodynamic Calculus - 2
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 12 - Thermodynamic Calculus - 3
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 13 - Thermodynamic Calculus - 4
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 14 - Legendre Transformation and Free-energy
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 15 - Criteria for phase equilibria
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 16 - Maxwell Relation
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 17 - Stability Criteria
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 18 - Thermodynamics of phase equilibrium
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 19 - Chemical potential and fugacity
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 20 - General discussion on fugacity
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 21 - Ideal Gas Mixture - Part 1
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 22 - Ideal Gas Mixture - Part 2
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 23 - Partial Molar Properties
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 24 - Partial Molar Properties from experimental data
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 25 - Thermodynamics properties from volumetric data - 1
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 26 - Thermodynamics properties from volumetric data - 2
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 27 - Fugacity of pure liquids and solids
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 28 - Thermodynamics properties from volumetric data: effect of V and T
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 29 - Approaches to phase equilibria calculation
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 30 - Traditional Approaches to phase equilibria calculations
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 31 - Algorithms for vapor-liquid equilibria
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 32 - Probability and Multiplicity
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 33 - Multiplicity and maximising the multiplicity
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 34 - Introduction to statistical mechanics
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 35 - Partition function for independent particles
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 36 - Intermolecular Forces
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 37 - Models of Molecular Pair Potentials
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 38 - Molecular Theory of Corresponding States
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 39 - Molecular Interactions in Dense Fluid Media
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 40 - Models for Electrolyte Systems
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 41 - Membrane Osmometry
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 42 - Fugacity of liquid mixture - 1
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 43 - Fugacity of liquid mixture - 2
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 44 - Models for fugacity of liquid mixtures - 1
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 45 - Models for fugacity of liquid mixtures - 2
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 46 - Examples of Fugacity of liquids
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 47 - Stability of the Fluid Phases
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 48 - Theories of Solution - I
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 49 - Theories of Solution - II
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 50 - Polymer Solutions
Link	NOC:Thermodynamics Of Fluid Phase Equilibria	Lecture 51 - Example Problems on Polymer Solutions
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 1 - Introduction
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 2 - Measurability and controllability of energy
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 3 - Postulates of thermodynamics - I
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 4 - Postulates of thermodynamics - II
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 5 - Definition of intensive variables and driving forces for temperature and pressure flow
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 6 - Driving force for the matter flow
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 7 - Basic properties, phase diagram, and thermodynamic table
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 8 - Work, and heat
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 9 - First law of thermodynamics for closed system: Ideal gas behavior
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 10 - First law of thermodynamics: Example 1
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 11 - First law of thermodynamics for open system
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 12 - First law of thermodynamics: Example 2
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 13 - The second law of the thermodynamics: Review
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 14 - Carnot cycle and thermodynamic temperature
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 15 - The concept of entropy
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 16 - Maximum work and entropy of ideal gas
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 17 - Power cycles and examples
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 18 - Mathematical properties of fundamental equations
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 19 - Generalized thermodynamic potential - I
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 20 - Generalized thermodynamic potential - II
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 21 - Multivariable Calculus
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 22 - Maxwell's relations and examples
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 23 - Jacobian method and its applications
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 24 - Equilibrium and stability - I
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 25 - Equilibrium and stability - II
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 26 - Stability criteria
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 27 - Intrinsic stability of thermodynamic system
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 28 - Phase transitions
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 29 - Clapeyron Equation and Vapour Pressure Correlations
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 30 - Equation of state
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 31 - Equation of state (Continued...)
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 32 - Repulsive Interaction
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 33 - Fugacity
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 34 - Thermodynamics of mixtures
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 35 - Partial molar properties and examples
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 36 - Examples of partial molar properties for real processes
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 37 - Obtaining the partial molar properties from experimental data
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 38 - Partial molar properties of ideal gas mixtures
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 39 - Chemical potential of ideal gas mixtures
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 40 - Fugacity coefficient in terms of measurable properties
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 41 - Fugacity coefficient for mixtures
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 42 - Fugacity coefficient for ideal mixtures
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 43 - Activity coefficient for mixtures
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 44 - Gibbs - Duhem relations and its impacts on the activity
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 45 - Excess Gibbs free energy model - I
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 46 - Two suffix Margules equation
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 47 - Excess Gibbs free energy model - II
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 48 - Vapor Liquid Equilibria
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 49 - Vapor Liquid Equilibria (examples)
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 50 - Vapor Liquid Equilibria (non-ideal mixtures - I)
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 51 - Vapor Liquid Equilibria (non-ideal mixtures - II)
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 52 - Azeotropes
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 53 - Azeotrope (binary mixture)
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 54 - Liquid-Liquid equilibria - 1
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 55 - liquid-liquid equilibria (Continued...) and solid-liquid equilibria
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 56 - Solid-liquid equilibria (Continued...)
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 57 - Solid-liquid equilibria examples and properties
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 58 - Examples of boiling point elevation
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 59 - Solubility of gases in the liquid
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 60 - Chemical reaction equilibria - I
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 61 - Chemical reaction equilibria - II
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 62 - Chemical reaction equilibria - III
Link	NOC:Chemical Engineering Thermodynamics (2019)	Lecture 63 - Chemical reaction equilibria - IV
Link	Biochemical Engineering	Lecture 1 - Fundamentals of Biology & Biotechnology
Link	Biochemical Engineering	Lecture 2 - Glimpses of Microbial World - Bacteria
Link	Biochemical Engineering	Lecture 3 - Virus and Cell Organelles
Link	Biochemical Engineering	Lecture 4 - Carbohydrate
Link	Biochemical Engineering	Lecture 5 - Nucleic Acid
Link	Biochemical Engineering	Lecture 6 - Lipids
Link	Biochemical Engineering	Lecture 7 - Proteins
Link	Biochemical Engineering	Lecture 8 - Biochemistry & Thermodynamics of Enzymes
Link	Biochemical Engineering	Lecture 9 - Enzyme Kinetics : Michealis-Menten Kinetics
Link	Biochemical Engineering	Lecture 10 - Regulation of Enzyme Activity : Inhibition
Link	Biochemical Engineering	Lecture 11 - Regulation of Enzyme Activity : Inhibition (Continued...)
Link	Biochemical Engineering	Lecture 12 - Effects of Substrate and Inhibition, pH and Temperature on Enzyme Activity
Link	Biochemical Engineering	Lecture 13 - Immobilized Enzymes
Link	Biochemical Engineering	Lecture 14 - Immobilized Enzymes (Continued...)
Link	Biochemical Engineering	Lecture 15 - Interphase Mass Transfer and Reaction in Immobilized Enzymes
Link	Biochemical Engineering	Lecture 16 - Interphase Mass Transfer and Reaction in Immobilized Enzymes (Continued...)
Link	Biochemical Engineering	Lecture 17 - Effectiveness Factor in Immobilized Enzymes
Link	Biochemical Engineering	Lecture 18 - Bioenergetics and Glycolysis
Link	Biochemical Engineering	Lecture 19 - TCA Cycle
Link	Biochemical Engineering	Lecture 20 - Electron Transport Chain & Oxidative Phosphorylation
Link	Biochemical Engineering	Lecture 21 - Pentose Phosphate Pathways Glycogenesis & Glycogenolysis
Link	Biochemical Engineering	Lecture 22 - Urea Cycle, Gluconeogenesis and Glyoxalate Cycle
Link	Biochemical Engineering	Lecture 23 - Microbial Growth : Phases and Models
Link	Biochemical Engineering	Lecture 24 - Effect of Mass Transfer on Microbial & Fungal Growth
Link	Biochemical Engineering	Lecture 25 - Effect of Multiple Substrates and Inhibition on Microbial Growth
Link	Biochemical Engineering	Lecture 26 - Design of Bioreactors
Link	Biochemical Engineering	Lecture 27 - Design of Chemostats
Link	Biochemical Engineering	Lecture 28 - Stability of Bioreactors
Link	Biochemical Engineering	Lecture 29 - Stability of Bioreactors (Continued...)
Link	Biochemical Engineering	Lecture 30 - Introduction to Receptor - Ligand Binding
Link	Biochemical Engineering	Lecture 31 - Effects of Ligand Depletion and Multiple Receptors on Binding Kinetics
Link	Biochemical Engineering	Lecture 32 - Effects of Ligand Depletion and Multiple Receptors on Binding Kinetics (Continued...)
Link	Biochemical Engineering	Lecture 33 - Receptors-Mediated Endocytosis
Link	Biochemical Engineering	Lecture 34 - Kinetics of Receptor-Mediated Endocytosis
Link	Biochemical Engineering	Lecture 35 - General Model for Receptor-Mediated Endocytosis
Link	Biochemical Engineering	Lecture 36 - Multiple Interacting Microbial Population: Prey-Predator Models
Link	Biochemical Engineering	Lecture 37 - Manufacture of Biochemicals
Link	Biochemical Engineering	Lecture 38 - Manufacture of Biochemicals (Continued...) & Strategies for Biomolecules Separation
Link	Biochemical Engineering	Lecture 39 - Strategies for Biomolecules Separation (Continued...)
Link	Biochemical Engineering	Lecture 40 - Strategies for Biomolecules Separation (Continued...)
Link	Microscale Transport Processes	Lecture 1 - Introduction
Link	Microscale Transport Processes	Lecture 2 - Introduction (Continued...)
Link	Microscale Transport Processes	Lecture 3 - Lab on Chip
Link	Microscale Transport Processes	Lecture 4 - Lab on Chip (Continued...)
Link	Microscale Transport Processes	Lecture 5 - Microscale manufacturing practices
Link	Microscale Transport Processes	Lecture 6 - Photolithography
Link	Microscale Transport Processes	Lecture 7 - Photolithography (Continued...)
Link	Microscale Transport Processes	Lecture 8 - Deposition
Link	Microscale Transport Processes	Lecture 9 - Plastic microfluidic devices
Link	Microscale Transport Processes	Lecture 10 - Mixing
Link	Microscale Transport Processes	Lecture 11 - Micro Heat Pipes
Link	Microscale Transport Processes	Lecture 12 - Mixing (Continued...)
Link	Microscale Transport Processes	Lecture 13 - Mixing (Continued...)
Link	Microscale Transport Processes	Lecture 14 - Micro Heat Pipes (Continued...)
Link	Microscale Transport Processes	Lecture 15 - Mixing (Continued...)
Link	Microscale Transport Processes	Lecture 16 - Dispersion
Link	Microscale Transport Processes	Lecture 17 - Dispersion (Continued...)
Link	Microscale Transport Processes	Lecture 18 - Dispersion (Continued...)
Link	Microscale Transport Processes	Lecture 19 - Electrowetting
Link	Microscale Transport Processes	Lecture 20 - Electro osmosis
Link	Microscale Transport Processes	Lecture 21 - Electrowetting (Continued...)
Link	Microscale Transport Processes	Lecture 22 - Electro osmosis (Continued...)
Link	Microscale Transport Processes	Lecture 23 - Dielectrophoresis
Link	Microscale Transport Processes	Lecture 24 - Dielectrophoresis (Continued...)
Link	Microscale Transport Processes	Lecture 25 - Dielectrophoresis (Continued...)
Link	Microscale Transport Processes	Lecture 26 - Scaling dimension and issues
Link	Microscale Transport Processes	Lecture 27 - Slip flow
Link	Microscale Transport Processes	Lecture 28 - Microstructured reactor
Link	Microscale Transport Processes	Lecture 29 - Immiscible flow in microchannel
Link	Microscale Transport Processes	Lecture 30 - Immiscible flow in microchannel (Continued...)
Link	Microscale Transport Processes	Lecture 31 - Immiscible flow in microchannel (Continued...)
Link	Microscale Transport Processes	Lecture 32 - Scaling dimension and issues (Continued...)
Link	Microscale Transport Processes	Lecture 33 - Immiscible flow in microchannel (Continued...)
Link	Microscale Transport Processes	Lecture 34 - Plastic device making
Link	Microscale Transport Processes	Lecture 35 - Transport processes and their descriptions
Link	Microscale Transport Processes	Lecture 36 - Convective fluid dynamics in microchannels
Link	Microscale Transport Processes	Lecture 37 - Microfluidic networks
Link	Microscale Transport Processes	Lecture 38 - Electrohydrodynamic atomization
Link	Microscale Transport Processes	Lecture 39 - Electrohydrodynamic atomization (Continued...)
Link	Microscale Transport Processes	Lecture 40 - Interfacial phenomena in thin liquid films
Link	Multiphase Flow	Lecture 1 - Introduction
Link	Multiphase Flow	Lecture 2 - Estimation of Flow Patterns
Link	Multiphase Flow	Lecture 3 - Estimation of Flow Patterns (Continued...)
Link	Multiphase Flow	Lecture 4 - Flow Pattern Maps Fascinating Taylor Bubbles
Link	Multiphase Flow	Lecture 5 - Definitions and Common Terminologies
Link	Multiphase Flow	Lecture 6 - Definitions and Common Terminologies (Continued...)
Link	Multiphase Flow	Lecture 7 - Simple Analytical Models
Link	Multiphase Flow	Lecture 8 - The Homogeneous Flow Theory
Link	Multiphase Flow	Lecture 9 - The Homogeneous Flow Theory (Continued...)
Link	Multiphase Flow	Lecture 10 - Compressible Flow A Recapitulation
Link	Multiphase Flow	Lecture 11 - Compressible Flow A Recapitulation (Continued...)
Link	Multiphase Flow	Lecture 12 - Choked Flow Condition for Homogeneous Flow
Link	Multiphase Flow	Lecture 13 - Drift Flux Model
Link	Multiphase Flow	Lecture 14 - Drift Flux Model (Continued...)
Link	Multiphase Flow	Lecture 15 - Drift Flux Model (Continued...)
Link	Multiphase Flow	Lecture 16 - Drift Flux Model (Continued...)
Link	Multiphase Flow	Lecture 17 - Separated Flow Model
Link	Multiphase Flow	Lecture 18 - Separated Flow Model (Continued...)
Link	Multiphase Flow	Lecture 19 - Separated Flow Model (Continued...)
Link	Multiphase Flow	Lecture 20 - Separated Flow Model - Condition of Choking
Link	Multiphase Flow	Lecture 21 - Separated Flow Model - Condition of Choking (Continued...)
Link	Multiphase Flow	Lecture 22 - Separated Flow Model - Estimation of Frictional Pressure Drop and Void Fraction
Link	Multiphase Flow	Lecture 23 - Separated Flow Model - Estimation of Frictional Pressure Drop and Void Fraction (Continued...)
Link	Multiphase Flow	Lecture 24 - Separated Flow Model - Estimation of Frictional Pressure Drop and Void Fraction (Continued...)
Link	Multiphase Flow	Lecture 25 - Separated Flow Model - Estimation of Frictional Pressure Drop and Void Fraction (Continued...)
Link	Multiphase Flow	Lecture 26 - Analysis of Specific Flow Regimes
Link	Multiphase Flow	Lecture 27 - Analysis of Specific Flow Regimes (Continued...)
Link	Multiphase Flow	Lecture 28 - Analysis of Specific Flow Regimes - Slug Flow (Continued...)
Link	Multiphase Flow	Lecture 29 - Two Phase Flow with Phase Change - An Introduction to Boiling Heat Transfer
Link	Multiphase Flow	Lecture 30 - Bubble Growth
Link	Multiphase Flow	Lecture 31 - Different Types of Nucleation
Link	Multiphase Flow	Lecture 32 - Ibullition from Hot Surfaces
Link	Multiphase Flow	Lecture 33 - Cycle of Bubble Growth and Departure
Link	Multiphase Flow	Lecture 34 - Heat Transfer in Different Regimes of Boiling
Link	Multiphase Flow	Lecture 35 - Heat Transfer in Different Regimes of Boiling (Continued...)
Link	Multiphase Flow	Lecture 36 - Critical Heat Flux, Film Boiling
Link	Multiphase Flow	Lecture 37 - Measurement Techniques for Two Phase flow Parameters
Link	Multiphase Flow	Lecture 38 - Measurement Techniques for Two Phase flow Parameters - Void Fraction Measurement
Link	Multiphase Flow	Lecture 39 - Measurement Techniques for Two Phase flow Parameters - Void Fraction Measurement (Continued...)
Link	Multiphase Flow	Lecture 40 - Measurement Techniques for Two Phase flow Parameters - Estimation of Flow Patterns
Link	Novel Separation Processes	Lecture 1 - Fundamentals of Separation Processes
Link	Novel Separation Processes	Lecture 2 - Identification of Novel Separation Processes
Link	Novel Separation Processes	Lecture 3 - Membrane Separation Processes
Link	Novel Separation Processes	Lecture 4 - Membrane Separation Processes (Continued...1)
Link	Novel Separation Processes	Lecture 5 - Membrane Separation Processes (Continued...2)
Link	Novel Separation Processes	Lecture 6 - Membrane Separation Processes (Continued...3)
Link	Novel Separation Processes	Lecture 7 - Membrane Separation Processes (Continued...4)
Link	Novel Separation Processes	Lecture 8 - Membrane Separation Processes (Continued...5)
Link	Novel Separation Processes	Lecture 9 - Membrane Separation Processes (Continued...6)
Link	Novel Separation Processes	Lecture 10 - Membrane Separation Processes (Continued...7)
Link	Novel Separation Processes	Lecture 11 - Membrane Separation Processes (Continued...8)
Link	Novel Separation Processes	Lecture 12 - Membrane Separation Processes (Continued...9)
Link	Novel Separation Processes	Lecture 13 - Membrane Separation Processes (Continued...10)
Link	Novel Separation Processes	Lecture 14 - Membrane Separation Processes (Continued...11)
Link	Novel Separation Processes	Lecture 15 - Membrane Separation Processes (Continued...12)
Link	Novel Separation Processes	Lecture 16 - Membrane Separation Processes (Continued...13)
Link	Novel Separation Processes	Lecture 17 - Membrane Separation Processes (Continued...14)
Link	Novel Separation Processes	Lecture 18 - Membrane Separation Processes (Continued...15)
Link	Novel Separation Processes	Lecture 19 - Membrane Separation Processes (Continued...16)
Link	Novel Separation Processes	Lecture 20 - Membrane Separation Processes (Continued...17)
Link	Novel Separation Processes	Lecture 21 - Membrane Separation Processes (Continued...18)
Link	Novel Separation Processes	Lecture 22 - External Field Induced Membrane Separation Processes
Link	Novel Separation Processes	Lecture 23 - External Field Induced Membrane Separation Processes (Continued...1)
Link	Novel Separation Processes	Lecture 24 - External Field Induced Membrane Separation Processes (Continued...2)
Link	Novel Separation Processes	Lecture 25 - External Field Induced Membrane Separation Processes (Continued...3)
Link	Novel Separation Processes	Lecture 26 - External Field Induced Membrane Separation Processes (Continued...4)
Link	Novel Separation Processes	Lecture 27 - Gas Separation
Link	Novel Separation Processes	Lecture 28 - Gas Separation (Continued...)
Link	Novel Separation Processes	Lecture 29 - Surfactant Based Separation Processes
Link	Novel Separation Processes	Lecture 30 - Surfactant Based Separation Processes (Continued...)
Link	Novel Separation Processes	Lecture 31 - Micellar Enhanced Ultrafiltration
Link	Novel Separation Processes	Lecture 32 - Micellar Enhanced Ultrafiltration (Continued...)
Link	Novel Separation Processes	Lecture 33 - Liquid Membranes
Link	Novel Separation Processes	Lecture 34 - Liquid Membranes (Continued...)
Link	Novel Separation Processes	Lecture 35 - Centrifugal Separation Processes
Link	Novel Separation Processes	Lecture 36 - Chromatographic Separation Processes
Link	Novel Separation Processes	Lecture 37 - Chromatographic Separation Processes (Continued...)
Link	Novel Separation Processes	Lecture 38 - Ion Exchange Processes
Link	Novel Separation Processes	Lecture 39 - Electrophoretic Separation Methods
Link	Novel Separation Processes	Lecture 40 - Electrophoretic Separation Methods (Continued...)
Link	Novel Separation Processes	Lecture 41 - Supercritical Fluid Extraction
Link	Process Control and Instrumentation	Lecture 1 - Introduction to Process Control
Link	Process Control and Instrumentation	Lecture 2 - Introduction to Process Control (Continued...)
Link	Process Control and Instrumentation	Lecture 3 - Mathematical Modeling (Continued...1)
Link	Process Control and Instrumentation	Lecture 4 - Mathematical Modeling (Continued...2)
Link	Process Control and Instrumentation	Lecture 5 - Mathematical Modeling (Continued...3)
Link	Process Control and Instrumentation	Lecture 6 - Dynamic Behavior of Chemical Processes
Link	Process Control and Instrumentation	Lecture 7 - Dynamic Behavior of Chemical Processes (Continued...1)
Link	Process Control and Instrumentation	Lecture 8 - Dynamic Behavior of Chemical Processes (Continued...2)
Link	Process Control and Instrumentation	Lecture 9 - Dynamic Behavior of Chemical Processes (Continued...3)
Link	Process Control and Instrumentation	Lecture 10 - Dynamic Behavior of Chemical Processes (Continued...4)
Link	Process Control and Instrumentation	Lecture 11 - Dynamic Behavior of Chemical Processes (Continued...5)
Link	Process Control and Instrumentation	Lecture 12 - Dynamic Behavior of Chemical Processes (Continued...6)
Link	Process Control and Instrumentation	Lecture 13 - Dynamic Behavior of Chemical Processes (Continued...7)
Link	Process Control and Instrumentation	Lecture 14 - Dynamic Behavior of Chemical Processes (Continued...8)
Link	Process Control and Instrumentation	Lecture 15 - Feedback Control Schemes
Link	Process Control and Instrumentation	Lecture 16 - Feedback Control Schemes (Continued...1)
Link	Process Control and Instrumentation	Lecture 17 - Feedback Control Schemes (Continued...2)
Link	Process Control and Instrumentation	Lecture 18 - Feedback Control Schemes (Continued...3)
Link	Process Control and Instrumentation	Lecture 19 - Feedback Control Schemes (Continued...4)
Link	Process Control and Instrumentation	Lecture 20 - Feedback Control Schemes (Continued...5)
Link	Process Control and Instrumentation	Lecture 21 - Feedback Control Schemes (Continued...6)
Link	Process Control and Instrumentation	Lecture 22 - Feedback Control Schemes (Continued...7)
Link	Process Control and Instrumentation	Lecture 23 - Feedback Control Schemes (Continued...8)
Link	Process Control and Instrumentation	Lecture 24 - Feedback Control Schemes (Continued...9)
Link	Process Control and Instrumentation	Lecture 25 - Feedback Control Schemes (Continued...10)
Link	Process Control and Instrumentation	Lecture 26 - Feedback Control Schemes (Continued...11)
Link	Process Control and Instrumentation	Lecture 27 - Feedback Control Schemes (Continued...12)
Link	Process Control and Instrumentation	Lecture 28 - Feedback Control Schemes (Continued...13)
Link	Process Control and Instrumentation	Lecture 29 - Feedback Control Schemes (Continued...14)
Link	Process Control and Instrumentation	Lecture 30 - Advanced Control Schemes
Link	Process Control and Instrumentation	Lecture 31 - Advanced Control Schemes (Continued...1)
Link	Process Control and Instrumentation	Lecture 32 - Advanced Control Schemes (Continued...2)
Link	Process Control and Instrumentation	Lecture 33 - Advanced Control Schemes (Continued...3)
Link	Process Control and Instrumentation	Lecture 34 - Advanced Control Schemes (Continued...4)
Link	Process Control and Instrumentation	Lecture 35 - Instrumentation: General Principles of Measurement Systems
Link	Process Control and Instrumentation	Lecture 36 - Instrumentation: General Principles of Measurement Systems (Continued...1)
Link	Process Control and Instrumentation	Lecture 37 - Instrumentation: General Principles of Measurement Systems (Continued...2)
Link	Process Control and Instrumentation	Lecture 38 - Instrumentation: General Principles of Measurement Systems (Continued...3)
Link	Process Control and Instrumentation	Lecture 39 - Instrumentation: General Principles of Measurement Systems (Continued...4)
Link	Process Control and Instrumentation	Lecture 40 - Instrumentation: General Principles of Measurement Systems (Continued...5)
Link	Process Control and Instrumentation	Lecture 41 - Transducer Elements
Link	Process Control and Instrumentation	Lecture 42 - Pressure Measurement
Link	Process Control and Instrumentation	Lecture 43 - Pressure Measurement (Continued...1)
Link	Process Control and Instrumentation	Lecture 44 - Pressure Measurement (Continued...2)
Link	Instability and Patterning of Thin Polymer Films	Lecture 1 - Introduction
Link	Instability and Patterning of Thin Polymer Films	Lecture 2 - Introduction (Continued...)
Link	Instability and Patterning of Thin Polymer Films	Lecture 3 - Some Fundamental Surface Related Concepts - I
Link	Instability and Patterning of Thin Polymer Films	Lecture 4 - Surface Tension (in terms of molecular interactions)
Link	Instability and Patterning of Thin Polymer Films	Lecture 5 - Effect Surface Tension : Laplace Pressure
Link	Instability and Patterning of Thin Polymer Films	Lecture 6 - Young Laplace Equation
Link	Instability and Patterning of Thin Polymer Films	Lecture 7 - Rayleish Instability
Link	Instability and Patterning of Thin Polymer Films	Lecture 8 - Meso Scale Fabrication Approaches
Link	Instability and Patterning of Thin Polymer Films	Lecture 9 - Photo Lithography - I
Link	Instability and Patterning of Thin Polymer Films	Lecture 10 - Photo Lithography - II
Link	Instability and Patterning of Thin Polymer Films	Lecture 11 - Photo Lithography - III
Link	Instability and Patterning of Thin Polymer Films	Lecture 12 - Photo Lithography - IV
Link	Instability and Patterning of Thin Polymer Films	Lecture 13 - Photo Lithography - V
Link	Instability and Patterning of Thin Polymer Films	Lecture 14 - Nano Imprint Lithography
Link	Instability and Patterning of Thin Polymer Films	Lecture 15 - Nano Imprint Lithography (Continued...)
Link	Instability and Patterning of Thin Polymer Films	Lecture 16 - Soft Lithography - I
Link	Instability and Patterning of Thin Polymer Films	Lecture 17 - Soft Lithography - II
Link	Instability and Patterning of Thin Polymer Films	Lecture 18 - Soft Lithography - III
Link	Instability and Patterning of Thin Polymer Films	Lecture 19 - Soft Lithography - IV
Link	Instability and Patterning of Thin Polymer Films	Lecture 20 - Soft Lithography - V
Link	Instability and Patterning of Thin Polymer Films	Lecture 21 - Soft Lithography - VI
Link	Instability and Patterning of Thin Polymer Films	Lecture 22 - Atomic Force Microscope - I
Link	Instability and Patterning of Thin Polymer Films	Lecture 23 - Atomic Force Microscope - II
Link	Instability and Patterning of Thin Polymer Films	Lecture 24 - Atomic Force Microscope - III
Link	Instability and Patterning of Thin Polymer Films	Lecture 25 - Atomic Force Microscope - IV
Link	Instability and Patterning of Thin Polymer Films	Lecture 26 - Atomic Force Microscope - V
Link	Instability and Patterning of Thin Polymer Films	Lecture 27 - Intermolecular Forces between Particles and Surfaces - I
Link	Instability and Patterning of Thin Polymer Films	Lecture 28 - Intermolecular Forces between Particles and Surfaces - II
Link	Instability and Patterning of Thin Polymer Films	Lecture 29 - Intermolecular Forces between Particles and Surfaces - III
Link	Instability and Patterning of Thin Polymer Films	Lecture 30 - Intermolecular Forces between Particles and Surfaces - IV
Link	Instability and Patterning of Thin Polymer Films	Lecture 31 - Spontaneous instability and dwetting of thin polymer film - I
Link	Instability and Patterning of Thin Polymer Films	Lecture 32 - Spontaneous instability and dwetting of thin polymer film - II
Link	Instability and Patterning of Thin Polymer Films	Lecture 33 - Spontaneous instability and dwetting of thin polymer film - III
Link	Instability and Patterning of Thin Polymer Films	Lecture 34 - Spontaneous instability and dwetting of thin polymer film - IV
Link	Instability and Patterning of Thin Polymer Films	Lecture 35 - Spontaneous instability and dwetting of thin polymer film - V
Link	Instability and Patterning of Thin Polymer Films	Lecture 36 - Spontaneous instability and dwetting of thin polymer film - VI
Link	Instability and Patterning of Thin Polymer Films	Lecture 37 - Spontaneous instability and dwetting of thin polymer film - VII
Link	Instability and Patterning of Thin Polymer Films	Lecture 38 - Template Guided Dewetting
Link	Instability and Patterning of Thin Polymer Films	Lecture 39 - Elastic Contact Instability and Lithography
Link	Instability and Patterning of Thin Polymer Films	Lecture 40 - Gradient Surfaces
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 1 - Introduction to vector space
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 2 - Introduction to vector space (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 3 - Onto, into, one to one function
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 4 - Vectors
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 5 - Vectors (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 6 - Contraction Mapping
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 7 - Contraction Mapping (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 8 - Matrix, Determinant
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 9 - Eigenvalue Problem in Discrete Domain
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 10 - Eigenvalue Problem in Discrete Domain (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 11 - Eigenvalue Problem in Discrete Domain (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 12 - Eigenvalue Problem in Discrete Domain (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 13 - Stability Analysis
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 14 - Stability Analysis (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 15 - Stability Analysis (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 16 - More Examples
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 17 - Partial Differential Equations
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 18 - Partial Differential Equations (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 19 - Eigenvalue Problem in Continuous Domain
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 20 - Special ODEs
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 21 - Adjoint Operator
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 22 - Theorems of Eigenvalues and Eigenfunction
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 23 - Solution PDE : Separation of Variables Method
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 24 - Solution of Parabolic PDE : Separation of variables method
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 25 - Solution of Parabolic PDE : Separation of Variables Method (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 26 - Solution of Higher Dimensional PDEs
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 27 - Solution of Higher Dimensional PDEs (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 28 - Four Dimensional Parabolic PDE
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 29 - Solution of Elliptic and Hyperbolic PDE
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 30 - Solution of Elliptic and Hyperbolic PDE (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 31 - PDE in Cylindrical and Spherical Coordinate
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 32 - Solution of non-homogeneous PDE
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 33 - Solution of non-homogeneous PDE (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 34 - Solution of non-homogeneous Parabolic PDE
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 35 - Solution of non-homogeneous Elliptic PDE
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 36 - Solution of non-homogeneous Elliptic PDE (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 37 - Similarity Solution
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 38 - Similarity Solution (Continued...)
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 39 - Integral Method
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 40 - Laplace Transform
Link	Advanced Mathematical Techniques in Chemical Engineering	Lecture 41 - Fourier Transform
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 1 - Fundamentals of Separation Processes and Introduction of Membrane System
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 2 - Fundamentals of Separation Processes and Introduction of Membrane System (Continued...)
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 3 - Fundamentals of Separation Processes and Introduction of Membrane System (Continued...)
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 4 - Fundamentals of Separation Processes and Introduction of Membrane System (Continued...)
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 5 - Modeling of Reverse Osmosis
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 6 - Concentration Polarization
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 7 - Osmotic Pressure Controlling Filtration
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 8 - Osmotic Pressure Controlling Filtration (Continued...)
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 9 - Osmotic Pressure Controlling Filtration (Continued...)
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 10 - Osmotic Pressure Controlling Filtration (Continued...)
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 11 - Osmotic Pressure Controlling Filtration (Continued...)
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 12 - Osmotic Pressure Controlling Filtration (Continued...)
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 13 - Modeling of Gel Layer Controlling Filtration
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 14 - Modeling of Gel Layer Controlling Filtration (Continued...)
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 15 - Modeling of Gel Layer Controlling Filtration (Continued...) and Resistance in Series Models
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 16 - Design of Membrane Module
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 17 - Design of Membrane Module (Continued...)
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 18 - Design of Membrane Module (Continued...)
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 19 - Modeling of Dialysis
Link	NOC:Introduction to Process Modeling in Membrane Separation Process	Lecture 20 - Modeling of Dialysis (Continued...)
Link	NOC:Soft Nano Technology	Lecture 1 - Introduction - 1
Link	NOC:Soft Nano Technology	Lecture 2 - Introduction - 2
Link	NOC:Soft Nano Technology	Lecture 3 - Introduction - 3
Link	NOC:Soft Nano Technology	Lecture 4 - Fundamental Concepts Related to Surface Tension - 1
Link	NOC:Soft Nano Technology	Lecture 5 - Fundamental Concepts Related to Surface Tension - 2
Link	NOC:Soft Nano Technology	Lecture 6 - Fundamental Concepts Related to Surface Tension - 3
Link	NOC:Soft Nano Technology	Lecture 7 - Fundamental Concepts Related to Surface Tension - 4
Link	NOC:Soft Nano Technology	Lecture 8 - Components of Surface Tension - 1
Link	NOC:Soft Nano Technology	Lecture 9 - Components of Surface Tension - 2
Link	NOC:Soft Nano Technology	Lecture 10 - Sell Assembly of Surfactant Molecules
Link	NOC:Soft Nano Technology	Lecture 11 - Laplace Pressure
Link	NOC:Soft Nano Technology	Lecture 12 - Photo Lithography - 1
Link	NOC:Soft Nano Technology	Lecture 13 - Photo Lithography - 2
Link	NOC:Soft Nano Technology	Lecture 14 - Photo Lithography - 3
Link	NOC:Soft Nano Technology	Lecture 15 - Photo Lithography - 4
Link	NOC:Soft Nano Technology	Lecture 16 - Photo Lithography - 5
Link	NOC:Soft Nano Technology	Lecture 17 - Photo Lithography - 6
Link	NOC:Soft Nano Technology	Lecture 18 - Soft Lithography - I
Link	NOC:Soft Nano Technology	Lecture 19 - Soft Lithography - 2
Link	NOC:Soft Nano Technology	Lecture 20 - Soft Lithography - 3
Link	NOC:Soft Nano Technology	Lecture 21 - Soft Lithography - 4
Link	NOC:Soft Nano Technology	Lecture 22 - Soft Lithography - 5
Link	NOC:Soft Nano Technology	Lecture 23 - Soft Lithography - 6
Link	NOC:Soft Nano Technology	Lecture 24 - Atomic Force Microscope - 1
Link	NOC:Soft Nano Technology	Lecture 25 - Atomic Force Microscope - 2
Link	NOC:Soft Nano Technology	Lecture 26 - Atomic Force Microscope - 3
Link	NOC:Soft Nano Technology	Lecture 27 - Atomic Force Microscope - 4
Link	NOC:Soft Nano Technology	Lecture 28 - Atomic Force Microscope - 5
Link	NOC:Soft Nano Technology	Lecture 29 - Atomic Force Microscope - 6
Link	NOC:Soft Nano Technology	Lecture 30 - Dewetting - 1
Link	NOC:Soft Nano Technology	Lecture 31 - Dewetting - 2
Link	NOC:Soft Nano Technology	Lecture 32 - VdW Interaction Between Two Surfaces
Link	NOC:Soft Nano Technology	Lecture 33 - Interaction Between Two Surfaces - 2
Link	NOC:Soft Nano Technology	Lecture 34 - Interaction Between Two Surfaces - 3
Link	NOC:Soft Nano Technology	Lecture 35 - Dewetting - 3
Link	NOC:Soft Nano Technology	Lecture 36 - Pattern Directed Dewetting - I
Link	NOC:Soft Nano Technology	Lecture 37 - Pattern Directed Dewetting - II
Link	NOC:Soft Nano Technology	Lecture 38 - Spin Dewetting
Link	NOC:Soft Nano Technology	Lecture 39 - Elastic Contact Instability - I
Link	NOC:Soft Nano Technology	Lecture 40 - Elastic Contact Instability - II
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 1 - Brief Introduction to Multiphase Flow
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 2 - Brief Introduction to Multiphase Flow (Continued...)
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 3 - Two Phase Flow through Micro Channels
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 4 - Two Phase Flow through Micro Channels (Continued...)
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 5 - Criteria for Confinement for in Case of Two Phase Flow
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 6 - Pertinent Dimensionless Numbers in Two Phase
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 7 - Flow Pattern Maps for Milli and Micro Systems
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 8 - Pattern Transition from Energy Minimisation Principle
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 9 - Experimental Identification of Flow Regimes
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 10 - Experimental Identification of Flow Regimes (Continued...)
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 11 - Flow Regimes and Void Fraction Estimation
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 12 - Influence of Operating Parameter on Flow Patterns
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 13 - Influence of Operating Parameter on Flow Patterns (Continued...)
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 14 - Influence of Operating Parameter on Flow Patterns (Continued...)
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 15 - Influence of Operating Parameter on Flow Patterns (Continued...)
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 16 - Void Fraction Characteristic Mini and Micro Channel
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 17 - Void Fraction and Pressure Drop in Reduced Dimensions - Experimental results
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 18 - Void Fraction and Pressure Drop in Reduced Dimensions - Experimental results (Continued...)
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 19 - Theoretical Analysis of Two Phase Flow in Reduced Dimensions
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 20 - Theoretical Analysis of Two Phase Flow in Reduced Dimensions (Continued...)
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 21 - Flow Pattern based Analysis in Micro Systems - Drift Flux Model
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 22 - Flow Pattern based Modelling - Slug Flow Model
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 23 - Flow Boiling in Microchannels
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 24 - Tutorial - I
Link	NOC:Adiabatic Two-Phase Flow & Flow Boiling in Microchannel	Lecture 25 - Tutorial - II
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 1 - Introduction
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 2 - Introduction (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 3 - First Law of Thermodynamics
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 4 - Second Law of Thermodynamics
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 5 - Second Law of Thermodynamics (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 6 - Entropy Change during Spontaneous Processes
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 7 - Criteria of Spontaneity
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 8 - Criteria of Spontaneity (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 9 - Thermodynamic Network
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 10 - Thermodynamic Network (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 11 - Tutorial 1
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 12 - Gibbs free energy as a function of temperature and pressure
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 13 - P-v-T behaviour of gases
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 14 - P-v-T behaviour (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 15 - P-v-T behaviour (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 16 - P-v-T behaviour (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 17 - Tutorial 2
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 18 - Property estimation from P-v-T behaviour
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 19 - Property estimation (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 20 - Concept of chemical potential
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 21 - Chemical potential (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 22 - Homogeneous open systems
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 23 - Homogeneous open systems (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 24 - Heterogeneous Closed Systems
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 25 - Tutorial 3
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 26 - Concept of fugacity
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 27 - Fugacity (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 28 - Estimation of fugacity coefficients
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 29 - Fugacity of condensed phase
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 30 - Mixtures
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 31 - Mixtures (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 32 - Tutorial 4
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 33 - Partial molar properties
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 34 - Partial molar properties (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 35 - Partial molar fugacity
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 36 - Ideal solutions
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 37 - Ideal solutions (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 38 - Ideal solutions (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 39 - Ideal solutions (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 40 - Non-ideal solutions
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 41 - Non-ideal solutions (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 42 - Non-ideal solutions (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 43 - Non-ideal solutions (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 44 - Non-ideal solutions (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 45 - Deviations from ideal dilute solutions
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 46 - Tutorial 5
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 47 - Tutorial 6
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 48 - Thermodynamics Consistency Test of VLE Data
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 49 - Retrograde Condensation
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 50 - Partial and Complete Immiscibility of Liquid Mixtures
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 51 - Partial and Complete Immiscibility of Liquid Mixtures (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 52 - Phase Equilibrium for Mass Transfer Processes
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 53 - Control Mass Analysis of Transient process
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 54 - Control Volume Analysis
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 55 - Throttling and problem
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 56 - Tutorial 7
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 57 - First Law for reacting systems
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 58 - Estimation of standard heat of reaction
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 59 - Effect of operating variables on heat of reaction
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 60 - Chemical Reaction Equilibrium
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 61 - Equilibrium constant and its estimation
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 62 - Relation of Equilibrium constant to composition
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 63 - Effect of operating conditions on equilibrium conversion
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 64 - Relation of Equilibrium constant to composition (Continued...)
Link	NOC:Phase Equilibrium Thermodynamics	Lecture 65 - Miscellaneous concepts on Reaction Equilibrium
Link	NOC:Transport Phenomena	Lecture 1 - Introduction : Newton's Law of Viscosity
Link	NOC:Transport Phenomena	Lecture 2 - Fourier and Fick's Laws
Link	NOC:Transport Phenomena	Lecture 3 - Shell Momentum Balance
Link	NOC:Transport Phenomena	Lecture 4 - Example of Shell Momentum Balance
Link	NOC:Transport Phenomena	Lecture 5 - Example of Shell Momentum Balance (Continued...)
Link	NOC:Transport Phenomena	Lecture 6 - Example of Shell Momentum Balance (Continued...)
Link	NOC:Transport Phenomena	Lecture 7 - Example of Shell Momentum Balance (Continued...)
Link	NOC:Transport Phenomena	Lecture 8 - Example of Shell Momentum Balance (Continued...)
Link	NOC:Transport Phenomena	Lecture 9 - Equations of Change for Isothermal Systems
Link	NOC:Transport Phenomena	Lecture 10 - Equations of Change for Isothermal Systems (Continued...)
Link	NOC:Transport Phenomena	Lecture 11 - Equations of Change for Isothermal Systems (Continued...)
Link	NOC:Transport Phenomena	Lecture 12 - Equations of Change for Isothermal Systems (Continued...)
Link	NOC:Transport Phenomena	Lecture 13 - Equations of Change for Isothermal Systems (Continued...)
Link	NOC:Transport Phenomena	Lecture 14 - Equations of Change for Isothermal Systems (Continued...)
Link	NOC:Transport Phenomena	Lecture 15 - Unsteady Flow
Link	NOC:Transport Phenomena	Lecture 16 - Boundary Layers
Link	NOC:Transport Phenomena	Lecture 17 - Boundary Layers (Continued...)
Link	NOC:Transport Phenomena	Lecture 18 - Boundary Layers (Continued...)
Link	NOC:Transport Phenomena	Lecture 19 - Boundary Layers (Continued...)
Link	NOC:Transport Phenomena	Lecture 20 - Boundary Layers (Continued...)
Link	NOC:Transport Phenomena	Lecture 21 - Boundary Layers (Continued...)
Link	NOC:Transport Phenomena	Lecture 22 - Boundary Layers (Continued...)
Link	NOC:Transport Phenomena	Lecture 23 - Boundary Layers (Continued...)
Link	NOC:Transport Phenomena	Lecture 24 - Boundary Layers (Continued...)
Link	NOC:Transport Phenomena	Lecture 25 - Turbulent Boundary Layers
Link	NOC:Transport Phenomena	Lecture 26 - Turbulent Boundary Layers (Continued...)
Link	NOC:Transport Phenomena	Lecture 27 - Turbulent Boundary Layers (Continued...)
Link	NOC:Transport Phenomena	Lecture 28 - Drag
Link	NOC:Transport Phenomena	Lecture 29 - Drag (Continued...)
Link	NOC:Transport Phenomena	Lecture 30 - Heat Transfer Basics
Link	NOC:Transport Phenomena	Lecture 31 - Heat Transfer Basics (Continued...)
Link	NOC:Transport Phenomena	Lecture 32 - 1-D Heat Conduction - Temperature Distributions
Link	NOC:Transport Phenomena	Lecture 33 - 1-D Heat Conduction - Shell Heat Balance
Link	NOC:Transport Phenomena	Lecture 34 - Shell Heat Balance
Link	NOC:Transport Phenomena	Lecture 35 - Viscous Dissipation
Link	NOC:Transport Phenomena	Lecture 36 - Transient Conduction
Link	NOC:Transport Phenomena	Lecture 37 - Transient Conduction (Continued...)
Link	NOC:Transport Phenomena	Lecture 38 - Forced Convection
Link	NOC:Transport Phenomena	Lecture 39 - Energy Equation
Link	NOC:Transport Phenomena	Lecture 40 - Energy Equation (Continued...)
Link	NOC:Transport Phenomena	Lecture 41 - Free Convection
Link	NOC:Transport Phenomena	Lecture 42 - Thermal Boundary Layer
Link	NOC:Transport Phenomena	Lecture 43 - Mass Transfer
Link	NOC:Transport Phenomena	Lecture 44 - Mass Transfer (Continued...)
Link	NOC:Transport Phenomena	Lecture 45 - Mass Transfer (Continued...)
Link	NOC:Transport Phenomena	Lecture 46 - Mass Transfer (Continued...)
Link	NOC:Transport Phenomena	Lecture 47 - Mass Transfer (Continued...)
Link	NOC:Transport Phenomena	Lecture 48 - Mass Transfer (Continued...)
Link	NOC:Transport Phenomena	Lecture 49 - Mass Transfer (Continued...)
Link	NOC:Transport Phenomena	Lecture 50 - Mass Transfer (Continued...)
Link	NOC:Transport Phenomena	Lecture 51 - Convection Transfer Equations
Link	NOC:Transport Phenomena	Lecture 52 - Boundary Layer Similarity
Link	NOC:Transport Phenomena	Lecture 53 - Boundary Layer - Analogy
Link	NOC:Transport Phenomena	Lecture 54 - Analogy - Tutorial I
Link	NOC:Transport Phenomena	Lecture 55 - Analogy - Tutorial II
Link	NOC:Transport Phenomena	Lecture 56 - Analogy - Tutorial III
Link	NOC:Transport Phenomena	Lecture 57 - Analogy - Tutorial IV and V
Link	NOC:Transport Phenomena	Lecture 58 - Tutorial on Displacement Thickness
Link	NOC:Transport Phenomena	Lecture 59 - Tutorial on Momentum Integral Equation
Link	NOC:Transport Phenomena	Lecture 60 - Summary of the Course
Link	NOC:Chemical Process Instrumentation	Lecture 1 - General Principles and Representation of Instruments
Link	NOC:Chemical Process Instrumentation	Lecture 2 - General Principles and Representation of Instruments (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 3 - General Principles and Representation of Instruments (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 4 - General Principles and Representation of Instruments (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 5 - General Principles and Representation of Instruments (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 6 - Performance Characteristics of Instruments and Data Analysis - I
Link	NOC:Chemical Process Instrumentation	Lecture 7 - Performance Characteristics of Instruments and Data Analysis - I (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 8 - Performance Characteristics of Instruments and Data Analysis - I (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 9 - Performance Characteristics of Instruments and Data Analysis - I (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 10 - Performance Characteristics of Instruments and Data Analysis - I (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 11 - Performance Characteristics of Instruments and Data Analysis - II
Link	NOC:Chemical Process Instrumentation	Lecture 12 - Performance Characteristics of Instruments and Data Analysis - II (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 13 - Performance Characteristics of Instruments and Data Analysis - II (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 14 - Performance Characteristics of Instruments and Data Analysis - II (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 15 - Performance Characteristics of Instruments and Data Analysis - II (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 16 - Transducer Elements
Link	NOC:Chemical Process Instrumentation	Lecture 17 - Transducer Elements (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 18 - Transducer Elements (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 19 - Transducer Elements (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 20 - Transducer Elements (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 21 - Pressure Measurement: Moderate and High Pressure Measuring Instruments
Link	NOC:Chemical Process Instrumentation	Lecture 22 - Pressure Measurement: Moderate and High Pressure Measuring Instruments (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 23 - Pressure Measurement: Moderate and High Pressure Measuring Instruments (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 24 - Pressure Measurement: Moderate and High Pressure Measuring Instruments (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 25 - Pressure Measurement: Moderate and High Pressure Measuring Instruments (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 26 - High Vacuum Measurement
Link	NOC:Chemical Process Instrumentation	Lecture 27 - High Vacuum Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 28 - High Vacuum Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 29 - High Vacuum Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 30 - Pressure Measurement
Link	NOC:Chemical Process Instrumentation	Lecture 31 - Temperature Measurement
Link	NOC:Chemical Process Instrumentation	Lecture 32 - Temperature Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 33 - Temperature Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 34 - Temperature Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 35 - Temperature Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 36 - Temperature Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 37 - Temperature Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 38 - Temperature Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 39 - Temperature Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 40 - Temperature Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 41 - Flow Measurement
Link	NOC:Chemical Process Instrumentation	Lecture 42 - Flow Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 43 - Flow Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 44 - Flow Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 45 - Flow Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 46 - Level Measurement
Link	NOC:Chemical Process Instrumentation	Lecture 47 - Level Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 48 - Level Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 49 - Level Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 50 - Level Measurement (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 51 - Miscellaneous Measurements : Composition
Link	NOC:Chemical Process Instrumentation	Lecture 52 - Miscellaneous Measurements : Composition (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 53 - Miscellaneous Measurements : Composition (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 54 - Miscellaneous Measurements : Composition (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 55 - Miscellaneous Measurements : Composition (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 56 - Pneumatic Control Valve
Link	NOC:Chemical Process Instrumentation	Lecture 57 - Pneumatic Control Valve (Continued...)
Link	NOC:Chemical Process Instrumentation	Lecture 58 - Pneumatic Control Valve (Continued...) and P&ID
Link	NOC:Chemical Process Instrumentation	Lecture 59 - GATE Questions
Link	NOC:Chemical Process Instrumentation	Lecture 60 - GATE Questions (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 1 - Introduction to Optimization
Link	NOC:Optimization in Chemical Engineering	Lecture 2 - Introduction to Optimization (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 3 - Introduction to Optimization (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 4 - Introduction of Optimization (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 5 - Introduction of Optimization (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 6 - Optimization Problem Formulation
Link	NOC:Optimization in Chemical Engineering	Lecture 7 - Optimization Problem Formulation (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 8 - Optimization Problem Formulation (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 9 - Optimization Problem Formulation (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 10 - Optimization Problem Formulation (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 11 - Basic Concepts of Optimization - I
Link	NOC:Optimization in Chemical Engineering	Lecture 12 - Basic Concepts of Optimization - I (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 13 - Basic Concepts of Optimization - I (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 14 - Basic Concepts of Optimization - I (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 15 - Basic Concepts of Optimization - I (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 16 - Basic Concepts of Optimization - II
Link	NOC:Optimization in Chemical Engineering	Lecture 17 - Basic Concepts of Optimization - II (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 18 - Basic Concepts of Optimization - II (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 19 - Basic Concepts of Optimization - II (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 20 - Basic Concepts of Optimization - II (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 21 - Unconstrained Single Variable Optimization: Methods and Applications (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 22 - Unconstrained Single Variable Optimization: Methods and Applications (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 23 - Unconstrained Single Variable Optimization: Methods and Applications (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 24 - Unconstrained Single Variable Optimization: Methods and Applications (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 25 - Unconstrained Single Variable Optimization: Methods and Applications (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 26 - Unconstrained Multivariable Optimization: Direct Search Methods
Link	NOC:Optimization in Chemical Engineering	Lecture 27 - Unconstrained Multivariable Optimization: Direct Search Methods (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 28 - Unconstrained Multivariable Optimization: Direct Search Methods (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 29 - Unconstrained Multivariable Optimization: Direct Search Methods (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 30 - Unconstrained Multivariable Optimization: Direct Search Methods (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 31 - Unconstrained Multivariable Optimization: Gradient Based Methods
Link	NOC:Optimization in Chemical Engineering	Lecture 32 - Unconstrained Multivariable Optimization: Gradient Based Methods (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 33 - Unconstrained Multivariable Optimization: Gradient Based Methods (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 34 - Unconstrained Multivariable Optimization: Gradient Based Methods (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 35 - Unconstrained Multivariable Optimization: Gradient Based Methods (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 36 - Introduction to Linear Programming
Link	NOC:Optimization in Chemical Engineering	Lecture 37 - Introduction to Linear Programming (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 38 - Introduction to Linear Programming (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 39 - Introduction to Linear Programming (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 40 - Introduction to Linear Programming (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 41 - Linear Programming - The Simplex Method
Link	NOC:Optimization in Chemical Engineering	Lecture 42 - Linear Programming - The Simplex Method (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 43 - Linear Programming - The Simplex Method (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 44 - Linear Programming - The Simplex Method (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 45 - Linear Programming - The Simplex Method (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 46 - Constrained Nonlinear Programming
Link	NOC:Optimization in Chemical Engineering	Lecture 47 - Constrained Nonlinear Programming (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 48 - Constrained Nonlinear Programming (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 49 - Constrained Nonlinear Programming (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 50 - Constrained Nonlinear Programming (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 51 - Applications of Optimization
Link	NOC:Optimization in Chemical Engineering	Lecture 52 - Applications of Optimization (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 53 - Applications of Optimization (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 54 - Applications of Optimization (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 55 - Applications of Optimization (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 56 - Software Tools for Optimization
Link	NOC:Optimization in Chemical Engineering	Lecture 57 - Software Tools for Optimization (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 58 - Software Tools for Optimization (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 59 - Software Tools for Optimization (Continued...)
Link	NOC:Optimization in Chemical Engineering	Lecture 60 - Software Tools for Optimization (Continued...)
Link	NOC:Heat Transfer (2018)	Lecture 1 - Introduction to Heat Transfer
Link	NOC:Heat Transfer (2018)	Lecture 2 - Introduction to Heat Transfer
Link	NOC:Heat Transfer (2018)	Lecture 3 - Heat Diffusion Equation
Link	NOC:Heat Transfer (2018)	Lecture 4 - Relevant Boundary Conditions in Conduction
Link	NOC:Heat Transfer (2018)	Lecture 5 - One Dimensional Steady State Conduction
Link	NOC:Heat Transfer (2018)	Lecture 6 - Temperature Distribution in Radial Systems
Link	NOC:Heat Transfer (2018)	Lecture 7 - Tutorial Problem on Critical Insulation Thickness
Link	NOC:Heat Transfer (2018)	Lecture 8 - Heat Source Systems
Link	NOC:Heat Transfer (2018)	Lecture 9 - Tutorial Problems of Heat Generating Systems
Link	NOC:Heat Transfer (2018)	Lecture 10 - Transient Conduction
Link	NOC:Heat Transfer (2018)	Lecture 11 - Lumped Capacitance (Continued...) and Tutorial Problem
Link	NOC:Heat Transfer (2018)	Lecture 12 - Transient heat Conduction
Link	NOC:Heat Transfer (2018)	Lecture 13 - Transient Conduction - Heisler Chart
Link	NOC:Heat Transfer (2018)	Lecture 14 - Heat Transfer from Extended Surface
Link	NOC:Heat Transfer (2018)	Lecture 15 - Fins and General Conduction Analysis
Link	NOC:Heat Transfer (2018)	Lecture 16 - Fundamentals of Convection
Link	NOC:Heat Transfer (2018)	Lecture 17 - Equations of Change for Non-isothermal Systems
Link	NOC:Heat Transfer (2018)	Lecture 18 - Equations of Change for Non-isothermal Systems (Continued...)
Link	NOC:Heat Transfer (2018)	Lecture 19 - Tutorial on the Application of Energy Equation
Link	NOC:Heat Transfer (2018)	Lecture 20 - Nusselt Number of a heated sphere in Stagnant Air
Link	NOC:Heat Transfer (2018)	Lecture 21 - Momentum and Thermal Boundary Layers
Link	NOC:Heat Transfer (2018)	Lecture 22 - The Flat Plate in Parallel Flow - Hydrodynamics and Momentum Transfer
Link	NOC:Heat Transfer (2018)	Lecture 23 - The Flat Plate in Parallel Flow - Heat Transfer
Link	NOC:Heat Transfer (2018)	Lecture 24 - The Effects of Turbulence
Link	NOC:Heat Transfer (2018)	Lecture 25 - Turbulent External Flow
Link	NOC:Heat Transfer (2018)	Lecture 26 - Heat and Momentum Transfer Analogy
Link	NOC:Heat Transfer (2018)	Lecture 27 - Mixed Boundary Layers
Link	NOC:Heat Transfer (2018)	Lecture 28 - Tutorial Problem on External Flow and Behavior of Heat Transfer Coefficient
Link	NOC:Heat Transfer (2018)	Lecture 29 - Tutorial Problem in External Flow and Convection
Link	NOC:Heat Transfer (2018)	Lecture 30 - Tutorial Problem in External Flow and Convection
Link	NOC:Heat Transfer (2018)	Lecture 31 - Tutorial Problem in External Flow and Convection
Link	NOC:Heat Transfer (2018)	Lecture 32 - Internal Flow Heat Transfer
Link	NOC:Heat Transfer (2018)	Lecture 33 - Internal Flow Heat Transfer (Continued...)
Link	NOC:Heat Transfer (2018)	Lecture 34 - Internal Flow Heat Transfer (Continued...)
Link	NOC:Heat Transfer (2018)	Lecture 35 - Internal Flow and Heat Transfer (Continued...)
Link	NOC:Heat Transfer (2018)	Lecture 36 - Internal Flow and Heat Transfer (Tutorial)
Link	NOC:Heat Transfer (2018)	Lecture 37 - Free Convection
Link	NOC:Heat Transfer (2018)	Lecture 38 - Heat Exchangers
Link	NOC:Heat Transfer (2018)	Lecture 39 - Heat Exchangers
Link	NOC:Heat Transfer (2018)	Lecture 40 - Heat Exchangers
Link	NOC:Heat Transfer (2018)	Lecture 41 - Tutorial Problems on Heat Exchanger Calculations
Link	NOC:Heat Transfer (2018)	Lecture 42 - Tutorial Problem on LMTD and Dirt Factor
Link	NOC:Heat Transfer (2018)	Lecture 43 - Epsilon-NTU Method - 1
Link	NOC:Heat Transfer (2018)	Lecture 44 - Epsilon-NTU Method - 1 (Continued...)
Link	NOC:Heat Transfer (2018)	Lecture 45 - Tutorial Problems on Epsilon - NTU Methods
Link	NOC:Heat Transfer (2018)	Lecture 46 - Tutorial Problems on Epsilon - NTU Methods
Link	NOC:Heat Transfer (2018)	Lecture 47 - Boiling, Evaporation and Evaporators
Link	NOC:Heat Transfer (2018)	Lecture 48 - Radiation - Fundamental Concepts
Link	NOC:Heat Transfer (2018)	Lecture 49 - Spectral Blackbody Radiation Intesity and Emissive Power
Link	NOC:Heat Transfer (2018)	Lecture 50 - Wein's Law, Stephen Boltzmann Law, Blackbody Radiation Function, Tutorial Problem
Link	NOC:Heat Transfer (2018)	Lecture 51 - Kirchhoff's Law
Link	NOC:Heat Transfer (2018)	Lecture 52 - Tutorial on Emissivity, Absroptivity and Blackbody Radiation Functions
Link	NOC:Heat Transfer (2018)	Lecture 53 - Solar Radiation and the Concept of View Factors
Link	NOC:Heat Transfer (2018)	Lecture 54 - Determination of View Factors
Link	NOC:Heat Transfer (2018)	Lecture 55 - Radiosity Blackbody Radiation Exchanges, Relevant Problem
Link	NOC:Heat Transfer (2018)	Lecture 56 - Network Method for Radiation Exchange in an Enclosure
Link	NOC:Heat Transfer (2018)	Lecture 57 - Network Method - Two and Three Zone Enclosures
Link	NOC:Heat Transfer (2018)	Lecture 58 - Tutorial Problem on Radiation Exhange using the Network Method
Link	NOC:Heat Transfer (2018)	Lecture 59 - Radiation Shields
Link	NOC:Heat Transfer (2018)	Lecture 60 - Gaseous Radiation (Participating Medium)
Link	NOC:Flow through Porous Media	Lecture 1 - Introduction (Definition Of Porous Media)
Link	NOC:Flow through Porous Media	Lecture 2 - Introduction (Conceptual Flow Models)
Link	NOC:Flow through Porous Media	Lecture 3 - Introduction (Applications)
Link	NOC:Flow through Porous Media	Lecture 4 - Mass Continuity (Introduction)
Link	NOC:Flow through Porous Media	Lecture 5 - Mass Continuity (Cartesian Coordinates)
Link	NOC:Flow through Porous Media	Lecture 6 - Mass Continuity (Cylindrical Coordinates)
Link	NOC:Flow through Porous Media	Lecture 7 - Mass Continuity (Radial Flow)
Link	NOC:Flow through Porous Media	Lecture 8 - Mass Continuity (Non-Uniform Permeability)
Link	NOC:Flow through Porous Media	Lecture 9 - Mass Continuity (Continued...)
Link	NOC:Flow through Porous Media	Lecture 10 - Mass Continuity (Streamlines And Potential Lines)
Link	NOC:Flow through Porous Media	Lecture 11 - Mass Continuity (Elementary Flow)
Link	NOC:Flow through Porous Media	Lecture 12 - Mass Continuity (Source/Sink)
Link	NOC:Flow through Porous Media	Lecture 13 - Mass Continuity (Superposition Of Elementary Flow)
Link	NOC:Flow through Porous Media	Lecture 14 - Mass Continuity (Superposition Of Elementary Flow) (Continued...)
Link	NOC:Flow through Porous Media	Lecture 15 - Transport Mechanisms (Introduction)
Link	NOC:Flow through Porous Media	Lecture 16 - Transport Mechanisms (Combined Mode)
Link	NOC:Flow through Porous Media	Lecture 17 - Transport Mechanisms (Adsorption/Pore Condensation)
Link	NOC:Flow through Porous Media	Lecture 18 - Transport Mechanisms (Continued...)
Link	NOC:Flow through Porous Media	Lecture 19 - Flow Equation (Introduction)
Link	NOC:Flow through Porous Media	Lecture 20 - Flow Equations (Continued...)
Link	NOC:Flow through Porous Media	Lecture 21 - Flow Equations (Viscous Flow in Capillary)
Link	NOC:Flow through Porous Media	Lecture 22 - Flow Equations (Packed Bed)
Link	NOC:Flow through Porous Media	Lecture 23 - Flow Equations (Fluidized Bed)
Link	NOC:Flow through Porous Media	Lecture 24 - Miscible Displacement (Uniform Velocity Over Capillary Cross-Section)
Link	NOC:Flow through Porous Media	Lecture 25 - Miscible Displacement (Laminar Flow in Capillary)
Link	NOC:Flow through Porous Media	Lecture 26 - Miscible Displacement (Movement of Concentration Pulse)
Link	NOC:Flow through Porous Media	Lecture 27 - Miscible Displacement (Step Change in Concentration)
Link	NOC:Flow through Porous Media	Lecture 28 - Miscible Displacement (Continued...)
Link	NOC:Flow through Porous Media	Lecture 29 - Miscible Displacement (Continued...)
Link	NOC:Flow through Porous Media	Lecture 30 - Miscible Displacement (Continued...)
Link	NOC:Flow through Porous Media	Lecture 31 - Miscible Displacement (Continued...)
Link	NOC:Flow through Porous Media	Lecture 32 - Miscible Displacement (Fractured Porous Media)
Link	NOC:Flow through Porous Media	Lecture 33 - Miscible Displacement (Viscous Front)
Link	NOC:Flow through Porous Media	Lecture 34 - Immiscible Flow
Link	NOC:Flow through Porous Media	Lecture 35 - Immiscible Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 36 - Immiscible Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 37 - Immiscible Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 38 - Immiscible Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 39 - Immiscible Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 40 - Immiscible Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 41 - IMMISCIBLE FLOW (Continued...)
Link	NOC:Flow through Porous Media	Lecture 42 - Immiscible Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 43 - Immiscible Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 44 - Immiscible Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 45 - Immiscible Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 46 - Immiscible Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 47 - Interception Of Suspended Solids
Link	NOC:Flow through Porous Media	Lecture 48 - Interception Of Suspended Solids (Continued...)
Link	NOC:Flow through Porous Media	Lecture 49 - Interception Of Suspended Solids (Continued...)
Link	NOC:Flow through Porous Media	Lecture 50 - Interception Of Suspended Solids (Continued...)
Link	NOC:Flow through Porous Media	Lecture 51 - Interception Of Suspended Solids (Continued...)
Link	NOC:Flow through Porous Media	Lecture 52 - Interception Of Suspended Solids (Continued...)
Link	NOC:Flow through Porous Media	Lecture 53 - Deformable Porous Media
Link	NOC:Flow through Porous Media	Lecture 54 - Deformable Porous Media (Continued...)
Link	NOC:Flow through Porous Media	Lecture 55 - Deformable Porous Media (Continued...)
Link	NOC:Flow through Porous Media	Lecture 56 - Heat Transfer With Fluid Flow
Link	NOC:Flow through Porous Media	Lecture 57 - Heat Transfer With Fluid Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 58 - Heat Transfer With Fluid Flow (Continued...)
Link	NOC:Flow through Porous Media	Lecture 59 - Characterization
Link	NOC:Flow through Porous Media	Lecture 60 - Characterization (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 1 - Solid particle characterization
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 2 - Solid particle characterization (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 3 - Particle size distribution
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 4 - Particle size distribution (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 5 - Particle size distribution (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 6 - Fluid - particle mechanics
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 7 - Fluid - particle mechanics (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 8 - Fluid - particle mechanics (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 9 - Fluid - particle mechanics (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 10 - Fluid - particle mechanics (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 11 - Fluid - particle mechanics (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 12 - Fluid - particle mechanics (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 13 - Fluid - particle mechanics (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 14 - Fluid - particle mechanics (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 15 - Fluid - particle mechanics (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 16 - Flow through packed beds
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 17 - Flow through packed beds (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 18 - Flow through packed beds (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 19 - Flow through packed beds (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 20 - Flow through packed beds (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 21 - Fluidization
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 22 - Fluidization (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 23 - Fluidization (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 24 - Fluidization (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 25 - Fluidization (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 26 - Sedimentation
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 27 - Sedimentation (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 28 - Sedimentation (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 29 - Sedimentation (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 30 - Sedimentation (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 31 - Filtration
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 32 - Filtration (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 33 - Filtration (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 34 - Filtration (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 35 - Filtration (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 36 - Centrifugal Separation
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 37 - Centrifugal Separation (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 38 - Centrifugal Separation (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 39 - Centrifugal Separation (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 40 - Centrifugal Separation (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 41 - Particle size reduction
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 42 - Particle size reduction (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 43 - Particle size reduction (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 44 - Particle size reduction (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 45 - Particle size reduction (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 46 - Particle size reduction (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 47 - Particle size enlargement
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 48 - Particle size enlargement (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 49 - Particle size enlargement (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 50 - Particle size enlargement (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 51 - Fluid - solid transport
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 52 - Fluid - solid transport (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 53 - Fluid - solid transport (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 54 - Fluid - solid transport (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 55 - Fluid - solid transport (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 56 - Colloids and nanoparticles
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 57 - Colloids and nanoparticles (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 58 - Colloids and nanoparticles (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 59 - Colloids and nanoparticles (Continued...)
Link	NOC:Fundamentals of Particle and Fluid Solid Processing	Lecture 60 - Colloids and nanoparticles (Continued...)
Link	NOC:Plant Design and Economics	Lecture 1 - Introduction
Link	NOC:Plant Design and Economics	Lecture 2 - Typical Design Steps
Link	NOC:Plant Design and Economics	Lecture 3 - Flow Diagram
Link	NOC:Plant Design and Economics	Lecture 4 - Flow Diagram - Mass and Energy Balance
Link	NOC:Plant Design and Economics	Lecture 5 - Piping and Instrumentation Diagram
Link	NOC:Plant Design and Economics	Lecture 6 - Selection of Process Equipment
Link	NOC:Plant Design and Economics	Lecture 7 - Process Utilities
Link	NOC:Plant Design and Economics	Lecture 8 - Plant Location
Link	NOC:Plant Design and Economics	Lecture 9 - Site and Plant Layout
Link	NOC:Plant Design and Economics	Lecture 10 - Heuristics in Process Synthesis and Design
Link	NOC:Plant Design and Economics	Lecture 11 - Capital Investment
Link	NOC:Plant Design and Economics	Lecture 12 - Capital Cost Estimates
Link	NOC:Plant Design and Economics	Lecture 13 - Cost Components in Capital Investments
Link	NOC:Plant Design and Economics	Lecture 14 - Methods of Capital Cost Estimates
Link	NOC:Plant Design and Economics	Lecture 15 - Estimation of Total Product Cost
Link	NOC:Plant Design and Economics	Lecture 16 - Different Types of Interest
Link	NOC:Plant Design and Economics	Lecture 17 - Continuous Interest, Cash Flow Diagram, Time Value of Money
Link	NOC:Plant Design and Economics	Lecture 18 - Uniform Cash Flows and Continuous Flows
Link	NOC:Plant Design and Economics	Lecture 19 - Income Tax and Depreciation
Link	NOC:Plant Design and Economics	Lecture 20 - Depreciation
Link	NOC:Plant Design and Economics	Lecture 21 - Cumulative Cash Flow and Profitability Standards
Link	NOC:Plant Design and Economics	Lecture 22 - Profitability Analysis
Link	NOC:Plant Design and Economics	Lecture 23 - Profitability Analysis (Continued...)
Link	NOC:Plant Design and Economics	Lecture 24 - Profitability Analysis (Continued...)
Link	NOC:Plant Design and Economics	Lecture 25 - Alternative Investment, Replacement and Sensitivity Analysis
Link	NOC:Plant Design and Economics	Lecture 26 - Introduction to Process Synthesis
Link	NOC:Plant Design and Economics	Lecture 27 - Hierarchical Approach to Process Synthesis - I
Link	NOC:Plant Design and Economics	Lecture 28 - Hierarchical Approach to Process Synthesis - II
Link	NOC:Plant Design and Economics	Lecture 29 - Hierarchical Approach to Process Synthesis - III
Link	NOC:Plant Design and Economics	Lecture 30 - Hierarchical Approach to Process Synthesis - IV
Link	NOC:Plant Design and Economics	Lecture 31 - Basic Reactor Principles
Link	NOC:Plant Design and Economics	Lecture 32 - Reactor Synthesis for Complex Reactions by Attainable Region: Fundamentals
Link	NOC:Plant Design and Economics	Lecture 33 - Reactor Synthesis for Complex Reactions by Attainable Region: Example-1
Link	NOC:Plant Design and Economics	Lecture 34 - Reactor Synthesis for Complex Reactions by Attainable Region: Example-2
Link	NOC:Plant Design and Economics	Lecture 35 - General Procedure for Reactor Design and Cost Estimation
Link	NOC:Plant Design and Economics	Lecture 36 - Introduction to Separation Systems
Link	NOC:Plant Design and Economics	Lecture 37 - Selection Criteria for Separation Processes
Link	NOC:Plant Design and Economics	Lecture 38 - Design of Multi-component Distillation Column: Short Cut Method
Link	NOC:Plant Design and Economics	Lecture 39 - Design of Multi-component Distillation Column: Short Cut Method - Example
Link	NOC:Plant Design and Economics	Lecture 40 - Introduction to Sequencing of Ordinary Distillation Columns
Link	NOC:Plant Design and Economics	Lecture 41 - Sequences for Simple Nonintegrated Distillation Columns
Link	NOC:Plant Design and Economics	Lecture 42 - Distillation Sequencing using Columns with Sidestreams
Link	NOC:Plant Design and Economics	Lecture 43 - Distillation Sequencing using Thermal Coupling
Link	NOC:Plant Design and Economics	Lecture 44 - Azeotropic Distillation: Residue Curve Maps
Link	NOC:Plant Design and Economics	Lecture 45 - Azeotropic Distillation Methods and Cost Estimation
Link	NOC:Plant Design and Economics	Lecture 46 - Introduction to Pinch Technology
Link	NOC:Plant Design and Economics	Lecture 47 - Composite Curves
Link	NOC:Plant Design and Economics	Lecture 48 - The Problem Table Method
Link	NOC:Plant Design and Economics	Lecture 49 - The Heat Recovery Pinch and The Grand Composite Curve
Link	NOC:Plant Design and Economics	Lecture 50 - Heat Exchanger Network Design
Link	NOC:Plant Design and Economics	Lecture 51 - Introduction
Link	NOC:Plant Design and Economics	Lecture 52 - Fires and Explosions: Flammability Characteristics
Link	NOC:Plant Design and Economics	Lecture 53 - Fires and Explosions: Prevention
Link	NOC:Plant Design and Economics	Lecture 54 - Toxic Release, Hazard Identification and MSDS
Link	NOC:Plant Design and Economics	Lecture 55 - Inherently Safer Design
Link	NOC:Plant Design and Economics	Lecture 56 - Optimality Criteria for Unconstrained Functions
Link	NOC:Plant Design and Economics	Lecture 57 - Examples
Link	NOC:Plant Design and Economics	Lecture 58 - Equality Constrained Problems: Langrange Multipliers
Link	NOC:Plant Design and Economics	Lecture 59 - Linear Programming Problems
Link	NOC:Plant Design and Economics	Lecture 60 - Batch Process Scheduling
Link	NOC:Colloids and Surfaces	Lecture 1 - Introduction and motivation
Link	NOC:Colloids and Surfaces	Lecture 2 - Colloidal dispersions, terminology and classification
Link	NOC:Colloids and Surfaces	Lecture 3 - Stability in colloids
Link	NOC:Colloids and Surfaces	Lecture 4 - Source, synthesis and characterisation of colloids
Link	NOC:Colloids and Surfaces	Lecture 5 - Characterisation of colloidal particles - I
Link	NOC:Colloids and Surfaces	Lecture 6 - Characterisation of colloidal particles - II
Link	NOC:Colloids and Surfaces	Lecture 7 - Introduction to forces acting on an individual colloidal particle
Link	NOC:Colloids and Surfaces	Lecture 8 - Introduction to interaction between colloidal particles
Link	NOC:Colloids and Surfaces	Lecture 9 - Application of Brownian force: Measument of diffusivity and size
Link	NOC:Colloids and Surfaces	Lecture 10 - Radiation used to study colloidal systems
Link	NOC:Colloids and Surfaces	Lecture 11 - Radiation used to study colloidal systems
Link	NOC:Colloids and Surfaces	Lecture 12 - Molecular origin of Van der waals forces
Link	NOC:Colloids and Surfaces	Lecture 13 - Vanderwaal interactions between particles
Link	NOC:Colloids and Surfaces	Lecture 14 - Problem on scaling of Vanderwaal interactions
Link	NOC:Colloids and Surfaces	Lecture 15 - Calculation of Vanderwaal's forces between semi-infinite blocks and Hamaker constant - I
Link	NOC:Colloids and Surfaces	Lecture 16 - Calculation of Vanderwaal's forces between semi-infinite blocks and Hamaker constant - II
Link	NOC:Colloids and Surfaces	Lecture 17 - Theories of Vanderwaal forces based on bulk properties and calculation of Hamaker constant using bulk properties
Link	NOC:Colloids and Surfaces	Lecture 18 - Effect of medium on Vanderwaal's interactions - I
Link	NOC:Colloids and Surfaces	Lecture 19 - Effect of medium on Vanderwaal's interactions - II
Link	NOC:Colloids and Surfaces	Lecture 20 - Colloid Polymer mixtures
Link	NOC:Colloids and Surfaces	Lecture 21 - Colloid polymer mixtures: colloid-solvent interactions and colloid-polymer interactions
Link	NOC:Colloids and Surfaces	Lecture 22 - Colloid polymer mixtures: Depletion flocculation
Link	NOC:Colloids and Surfaces	Lecture 23 - Colloid polymer mixtures: Depletion stabilisation
Link	NOC:Colloids and Surfaces	Lecture 24 - Depletion interactions
Link	NOC:Colloids and Surfaces	Lecture 25 - Steric interactions/osmotic repulsion
Link	NOC:Colloids and Surfaces	Lecture 26 - Tutorial problem on depletion interactions
Link	NOC:Colloids and Surfaces	Lecture 27 - Colloidal Interactions: Introduction to electrostatic interactions/electrical double layer interactions
Link	NOC:Colloids and Surfaces	Lecture 28 - Introduction to models of electrical double layer: Helmholtz model/capacitor model
Link	NOC:Colloids and Surfaces	Lecture 29 - Review and summary of Helmholtz model (or capacitor model) of electrical double layer
Link	NOC:Colloids and Surfaces	Lecture 30 - Models of electrical double layer: Diffuse double layer model/Gouy-Chapman model
Link	NOC:Colloids and Surfaces	Lecture 31 - Potential distribution near planar surfaces: Derivation of the Poisson-Boltzmann equation
Link	NOC:Colloids and Surfaces	Lecture 32 - Potential distribution near planar surfaces: Solution to the linearised Poisson-Boltzmann equation
Link	NOC:Colloids and Surfaces	Lecture 33 - Potential distribution near spherical surfaces: Solution to linearised Poisson-Boltzmann equation
Link	NOC:Colloids and Surfaces	Lecture 34 - Comparison of Capacitor model and Diffuse double layer model
Link	NOC:Colloids and Surfaces	Lecture 35 - Models of electrical double layer: Gouy Chapman Theory - I
Link	NOC:Colloids and Surfaces	Lecture 36 - Models of electrical double layer: Gouy Chapman Theory - II
Link	NOC:Colloids and Surfaces	Lecture 37 - Structure of Electrical double layer
Link	NOC:Colloids and Surfaces	Lecture 38 - Force of Repulsion between interacting surfaces
Link	NOC:Colloids and Surfaces	Lecture 39 - Potential Energy of repulsion between Planar double layers and DLVO Theory
Link	NOC:Colloids and Surfaces	Lecture 40 - Zeta Potential and Electrophoretic mobility of an ion
Link	NOC:Colloids and Surfaces	Lecture 41 - Electrokinetic Phenomena
Link	NOC:Colloids and Surfaces	Lecture 42 - Relation between Electrophoretic mobility and Zeta potential - I
Link	NOC:Colloids and Surfaces	Lecture 43 - Relation between Electrophoretic mobility and Zeta potential - II
Link	NOC:Colloids and Surfaces	Lecture 44 - Colloidal particles at interfaces:Introduction
Link	NOC:Colloids and Surfaces	Lecture 45 - Characterization of Particles at interface
Link	NOC:Colloids and Surfaces	Lecture 46 - Experimental Observations -Concept of Electrostatic interactions and Stability at interfaces
Link	NOC:Colloids and Surfaces	Lecture 47 - Implications from Surface energy balances and Estimation of energy required for detachment
Link	NOC:Colloids and Surfaces	Lecture 48 - Colloidal interactions at interface
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 1 - Why are polymers so common?
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 2 - Polymers: Molecular structure
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 3 - Process, structure, property
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 4 - Biopolymers
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 5 - Molecular weight and distribution
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 6 - Polymerization
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 7 - Macromolecular nature
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 8 - Renewable sources for polymers
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 9 - Polymerization/depolymerization
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 10 - States of interest
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 11 - Application based terms
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 12 - Reuse and repurpose
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 13 - Molecular conformations
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 14 - Size, mobility and flexibility
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 15 - Polyelectrolytes
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 16 - Structures in biopolymers
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 17 - Amorphous/crystalline states - 1
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 18 - Amorphous/crystalline states - 2
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 19 - Orientation
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 20 - Interactions
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 21 - Kinetics of crystallization
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 22 - Glass transition - 1
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 23 - Glass transition - 2
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 24 - States in environment
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 25 - Liquid crystalline polymers
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 26 - Copolymers - 1
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 27 - Copolymers - 2
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 28 - Blends - 1
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 29 - Blends - 2
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 30 - Microstructure in polymers
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 31 - Composites
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 32 - Stress strain response
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 33 - Additives for polymeric systems
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 34 - Blends/composites in recycling
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 35 - Physical/chemical crosslinking
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 36 - Mechanical properties - I
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 37 - Mechanical properties - II
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 38 - Physical and chemical aging
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 39 - Solutions: properties
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 40 - Conducting polymers
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 41 - Dielectric response - I
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 42 - Dielectric response - II
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 43 - Plasticity
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 44 - Properties of composites
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 45 - Viscoelasticity: introduction
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 46 - Thermal response
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 47 - Viscoelasticity: characterization
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 48 - Viscoelasticity: simple models
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 49 - Dynamic Mechanical analysis
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 50 - Damping Applications
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 51 - Time Temperature superposition
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 52 - Impact and energy absorption
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 53 - Testing for applications
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 54 - Properties of blends
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 55 - Biomimetic polymers
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 56 - Advanced mechanics
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 57 - Viscoelastic response: examples
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 58 - Polymer packaging
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 59 - Porous polymers/membranes
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 60 - Polymer at interfaces
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 61 - Diffusion in polymers
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 62 - Compatibilizers
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 63 - Biopolymer applications
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 64 - Adhesives and Paints
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 65 - Dissolution and recovery
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 66 - Polymerization kinetics
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 67 - Polymerization reactors
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 68 - Polymer processing - I
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 69 - Polymer processing - II
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 70 - Polymer processing - III
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 71 - Flow simulations
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 72 - Processing for recycling
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 73 - Recycle, up-down cycling - I
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 74 - Recycle, up-down cycling - II
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 75 - Flow behaviour - rheology
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 76 - Crosslinking
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 77 - Conversion of polymers
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 78 - Rheology and entanglement
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 79 - Rheological models
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 80 - Rheology and processing
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 81 - Absorption and leaching
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 82 - Swelling of polymers
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 83 - Viscosity for polymer processing
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 84 - Microplastics, aerosols, sediments
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 85 - Biodegradation of polymers
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 86 - Biodegradable polymers - 1
Link	NOC:Polymers: Concepts, Properties, Uses and Sustainability	Lecture 87 - Biodegradable polymers - 2
Link	NOC:Material and Energy Balance Computations	Lecture 1 - Introduction to Engineering Calculations
Link	NOC:Material and Energy Balance Computations	Lecture 2 - Introduction to Engineering Calculations (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 3 - Introduction to Engineering Calculations (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 4 - Introduction to Processes and Process Variables
Link	NOC:Material and Energy Balance Computations	Lecture 5 - Introduction to Processes and Process Variables (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 6 - Fundamentals of Material Balance
Link	NOC:Material and Energy Balance Computations	Lecture 7 - Fundamentals of Material Balance (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 8 - Fundamentals of Material Balance (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 9 - Fundamentals of Material Balance (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 10 - Material Balance of Single-unit
Link	NOC:Material and Energy Balance Computations	Lecture 11 - Material Balance of Multiple Units
Link	NOC:Material and Energy Balance Computations	Lecture 12 - Material Balance of Multiple Units (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 13 - Material Balance of Multiple Units (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 14 - Material Balance of Multiple Units (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 15 - Material Balance of Multiple Units - Recycle
Link	NOC:Material and Energy Balance Computations	Lecture 16 - Material Balance of Recycle and Bypass Units
Link	NOC:Material and Energy Balance Computations	Lecture 17 - Material Balance of Recycle and Bypass Units (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 18 - Introduction
Link	NOC:Material and Energy Balance Computations	Lecture 19 - Introduction (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 20 - Introduction (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 21 - Multiple reactions and reactive process balance
Link	NOC:Material and Energy Balance Computations	Lecture 22 - Reactive process balance
Link	NOC:Material and Energy Balance Computations	Lecture 23 - Multiple reactions and reactive process balance
Link	NOC:Material and Energy Balance Computations	Lecture 24 - Reactive process balance (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 25 - Reactive process balance (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 26 - Combustion reactions balance
Link	NOC:Material and Energy Balance Computations	Lecture 27 - Combustion reactions balance (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 28 - Single-phase systems
Link	NOC:Material and Energy Balance Computations	Lecture 29 - Single phase systems (Continued...)
Link	NOC:Material and Energy Balance Computations	Lecture 30 - Single-phase problems and concept of multi-phase system
Link	NOC:Material and Energy Balance Computations	Lecture 31 - Introduction to Energy Balance - I
Link	NOC:Material and Energy Balance Computations	Lecture 32 - Introduction to Energy Balance - II
Link	NOC:Material and Energy Balance Computations	Lecture 33 - Introduction to Energy Balance - III
Link	NOC:Material and Energy Balance Computations	Lecture 34 - Introduction to Energy Balance - IV
Link	NOC:Material and Energy Balance Computations	Lecture 35 - Introduction to Energy Balance - V
Link	NOC:Material and Energy Balance Computations	Lecture 36 - Introduction to Energy Balance - VI
Link	NOC:Material and Energy Balance Computations	Lecture 37 - Introduction to Energy Balance - VII
Link	NOC:Material and Energy Balance Computations	Lecture 38 - Introduction to Energy Balance - VIII
Link	NOC:Material and Energy Balance Computations	Lecture 39 - Introduction to Energy Balance - IX
Link	NOC:Material and Energy Balance Computations	Lecture 40 - Introduction to Energy Balance - X
Link	NOC:Material and Energy Balance Computations	Lecture 41 - Introduction to Energy Balance - XI
Link	NOC:Material and Energy Balance Computations	Lecture 42 - Estimation of Physical Properties - I
Link	NOC:Material and Energy Balance Computations	Lecture 43 - Estimation of Physical Properties - II
Link	NOC:Material and Energy Balance Computations	Lecture 44 - Estimation of Physical Properties - III
Link	NOC:Material and Energy Balance Computations	Lecture 45 - Tutorial - I
Link	NOC:Material and Energy Balance Computations	Lecture 46 - Tutorial - II
Link	NOC:Material and Energy Balance Computations	Lecture 47 - Tutorial - III
Link	NOC:Material and Energy Balance Computations	Lecture 48 - Tutorial - IV
Link	NOC:Material and Energy Balance Computations	Lecture 49 - Estimation of Physical Parameters - IV
Link	NOC:Material and Energy Balance Computations	Lecture 50 - Estimation of Physical Parameters - V
Link	NOC:Material and Energy Balance Computations	Lecture 51 - Energy Balance with Chemical Reactions - I
Link	NOC:Material and Energy Balance Computations	Lecture 52 - Energy Balance with Chemical Reactions - II
Link	NOC:Material and Energy Balance Computations	Lecture 53 - Energy Balance with Chemical Reactions - III
Link	NOC:Material and Energy Balance Computations	Lecture 54 - Energy Balance with Chemical Reactions - IV
Link	NOC:Material and Energy Balance Computations	Lecture 55 - Energy Balance with Chemical Reactions - V
Link	NOC:Material and Energy Balance Computations	Lecture 56 - Energy Balance with Chemical Reactions - VI
Link	NOC:Material and Energy Balance Computations	Lecture 57 - Humidity and Psychrometric Chart - I
Link	NOC:Material and Energy Balance Computations	Lecture 58 - Humidity and Psychrometric Chart - II
Link	NOC:Material and Energy Balance Computations	Lecture 59 - Humidity and Psychrometric Chart - III
Link	NOC:Material and Energy Balance Computations	Lecture 60 - Humidity and Psychrometric Chart - IV
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 1 - Introduction
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 2 - Introduction (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 3 - Optimum design and design documentation
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 4 - Introduction to Mass Transfer Processes
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 5 - Phase Equillibrium
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 6 - Phase Equillibrium (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 7 - Phase Equillibrium (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 8 - Distillation
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 9 - Flash Distillation and Design problem
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 10 - Fractionation
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 11 - Fractionation (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 12 - McCabe-Thiele construction for number of ideal stages
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 13 - Optimum Design
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 14 - Multi-component fractionation design
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 15 - Batch Distillation
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 16 - Practical issues in desigining distillation processes
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 17 - Design of absorbers
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 18 - Design of absorbers (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 19 - Design of absorbers (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 20 - Tower and Tower internals
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 21 - Tower and Tower internals (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 22 - Tower and Tower internals (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 23 - Sieve Tray Design
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 24 - Sieve Tray Design (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 25 - Sieve Tray Design (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 26 - Bubble Cap Tray Design
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 27 - Bubble Cap Tray Design (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 28 - Bubble Cap Tray Design (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 29 - Tower and Tower internals (Packed Tower Design)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 30 - Tower and Tower internals (Packed Tower Design) (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 31 - Adsorption
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 32 - Packed bed adsorption
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 33 - Packed bed adsorber design
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 34 - Packed bed adsorber design (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 35 - Liquid-liquid extraction (LLE)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 36 - Liquid-liquid extraction (L2)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 37 - Liquid-liquid extraction (L3)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 38 - Liquid-liquid extraction (L4)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 39 - Liquid-liquid extraction (L5)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 40 - Design of Mass Transfer Processes (Review)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 41 - Design of Heat Transfer Processes - Introduction
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 42 - Double Pipe Heat exchanger
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 43 - Double Pipe Heat exchanger (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 44 - Double Pipe Heat exchanger (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 45 - Design of Shell and Tube Heat Exchangers - a general overview
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 46 - Design of Shell and Tube Heat Exchangers - a general overview (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 47 - Shell and Tube Heat Exchanger - Design
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 48 - Shell and Tube Heat Exchanger - Design
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 49 - Heat exchanger Network Analysis
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 50 - Heat exchanger Network Analysis (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 51 - Heat exchanger Network Analysis (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 52 - Heat exchanger Network Analysis (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 53 - Heat exchanger Network Analysis (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 54 - Plant Hydraulics
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 55 - Plant Hydraulics (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 56 - Plant Hydraulics (Continued...)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 57 - Plant Hydraulics (End)
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 58 - Process Vessels
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 59 - Process Instrumentation and Control
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 60 - Engineered Safety
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 61 - Process Utilities
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 62 - Process Design using Simulators
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 63 - Process Packages
Link	NOC:Principles and Practices of Process Equipment and Plant Design	Lecture 64 - Design of a 10 TPD Mono-nitrotoluene plant
Link	Chemical Engineering Thermodynamics	Lecture 1 - Thermodynamics and the Chemical Industry
Link	Chemical Engineering Thermodynamics	Lecture 2 - James Prescot Joule and the first law
Link	Chemical Engineering Thermodynamics	Lecture 3 - Sadi Carnot and the second law
Link	Chemical Engineering Thermodynamics	Lecture 4 - Equilibrium and Extrema in work
Link	Chemical Engineering Thermodynamics	Lecture 5 - Illustrative Calculations - I
Link	Chemical Engineering Thermodynamics	Lecture 6 - Properties of pure substances
Link	Chemical Engineering Thermodynamics	Lecture 7 - The p-h chart
Link	Chemical Engineering Thermodynamics	Lecture 8 - Work calculation
Link	Chemical Engineering Thermodynamics	Lecture 9 - Illustrative Calculations - II
Link	Chemical Engineering Thermodynamics	Lecture 10 - Heat-Work Interconversion Devices
Link	Chemical Engineering Thermodynamics	Lecture 11 - Refrigeration / Thermodynamics of mixtures
Link	Chemical Engineering Thermodynamics	Lecture 12 - The Gibbs Duhem equation
Link	Chemical Engineering Thermodynamics	Lecture 13 - Models for Excess Gibbs Free Energy
Link	Chemical Engineering Thermodynamics	Lecture 14 - Van Laar model
Link	Chemical Engineering Thermodynamics	Lecture 15 - Gaseous and liquid mixtures
Link	Chemical Engineering Thermodynamics	Lecture 16 - Separation Work / Equations of state
Link	Chemical Engineering Thermodynamics	Lecture 17 - Chemical potentials in gas and condensed phases
Link	Chemical Engineering Thermodynamics	Lecture 18 - Vapour Liquid Equilibria - I
Link	Chemical Engineering Thermodynamics	Lecture 19 - Vapour Liquid Equilibria - II
Link	Chemical Engineering Thermodynamics	Lecture 20 - Solvent-Solvent mixtures
Link	Chemical Engineering Thermodynamics	Lecture 21 - Solvent-Solute mixtures
Link	Chemical Engineering Thermodynamics	Lecture 22 - Liquid-liquid equilibria
Link	Chemical Engineering Thermodynamics	Lecture 23 - An industrial example
Link	Chemical Engineering Thermodynamics	Lecture 24 - Liquid-liquid equilibria / Reaction Equilibria
Link	Chemical Engineering Thermodynamics	Lecture 25 - Reaction Equilibria
Link	Chemical Engineering Thermodynamics	Lecture 26 - Illustrative Examples - I
Link	Chemical Engineering Thermodynamics	Lecture 27 - Illustrative Examples - II
Link	Chemical Engineering Thermodynamics	Lecture 28 - Illustrative Examples - III
Link	Chemical Engineering Thermodynamics	Lecture 29 - Simultaneous Relations
Link	Chemical Engineering Thermodynamics	Lecture 30 - Thermodynamic Consistency / Reverse Osmosis
Link	Chemical Engineering Thermodynamics	Lecture 31 - Miscellaneous topics in phase equilibria
Link	Chemical Engineering Thermodynamics	Lecture 32 - Absorption Refrigeration
Link	Chemical Engineering Thermodynamics	Lecture 33 - Summary of Classical Thermodynamics
Link	Chemical Engineering Thermodynamics	Lecture 34 - Molecular basis of Thermodynamics - I
Link	Chemical Engineering Thermodynamics	Lecture 35 - Molecular basis of Thermodynamics - II
Link	Computational Fluid Dynamics	Lecture 1 - Motivation for CFD and Introduction to the CFD approach
Link	Computational Fluid Dynamics	Lecture 2 - Illustration of the CFD approach through a worked out example
Link	Computational Fluid Dynamics	Lecture 3 - Eulerian approach, Conservation Equation, Derivation of Mass Conservation Equation and Statement of the momentum conservation equation
Link	Computational Fluid Dynamics	Lecture 4 - Forces acting on a control volume; Stress tensor; Derivation of the momentum conservation equation ; Closure problem; Deformation of a fluid element in fluid flow
Link	Computational Fluid Dynamics	Lecture 5 - Kinematics of deformation in fluid flow; Stress vs strain rate relation; Derivation of the Navier-Stokes equations
Link	Computational Fluid Dynamics	Lecture 6 - Equations governing flow of incompressible flow; Initial and boundary conditions; Wellposedness of a fluid flow problem
Link	Computational Fluid Dynamics	Lecture 7 - Equations for some simple cases; Generic scalar transport equation form of the governing equations; Outline of the approach to the solution of the N-S equations.
Link	Computational Fluid Dynamics	Lecture 8 - cut out the first 30s; Spatial discretization of a simple flow domain; Taylor’s series expansion and the basis of finite difference approximation of a derivative; Central and one-sided difference approximations; Order of accuracy of finite difference ap
Link	Computational Fluid Dynamics	Lecture 9 - Finite difference approximation of pth order of accuracy for qth order derivative; cross -derivatives; Examples of high order accurate formulae for several derivatives
Link	Computational Fluid Dynamics	Lecture 10 - One -sided high order accurate approximations; Explicit and implicit formulations for the time derivatives
Link	Computational Fluid Dynamics	Lecture 11 - Numerical solution of the unsteady advection equation using different finite difference approximations
Link	Computational Fluid Dynamics	Lecture 12 - Need for analysis of a discretization scheme; Concepts of consistency, stability and convergence and the equivalence theorem of Lax ; Analysis for consistency
Link	Computational Fluid Dynamics	Lecture 13 - Statement of the stability problem; von Neumann stability analysis of the first order wave equation
Link	Computational Fluid Dynamics	Lecture 14 - Consistency and stability analysis of the unsteady diffusion equation; Analysis for two- and three -dimensional cases; Stability of implicit schemes
Link	Computational Fluid Dynamics	Lecture 15 - Interpretation of the stability condition; Stability analysis of the generic scalar equation and the concept of upwinding ; Diffusive and dissipative errors in numerical solution; Introduction to the concept of TVD schemes
Link	Computational Fluid Dynamics	Lecture 16 - Template for the generic scalar transport equation and its extension to the solution of Navier-Stokes equa tions for a compressible flow.
Link	Computational Fluid Dynamics	Lecture 17 - Illustration of application of the template using the MacCormack scheme for a three-dimensional compressible flow
Link	Computational Fluid Dynamics	Lecture 18 - Stability limits of MacCormack scheme; Limitations in extending compressible flow schemes to incompre ssible flows ; Difficulty of evaluation of pressure in incompressible flows and listing of various approaches
Link	Computational Fluid Dynamics	Lecture 19 - Artificial compressibility method and the streamfunction-vorticity method for the solution of NS equations and their limitations
Link	Computational Fluid Dynamics	Lecture 20 - Pressur e equation method for the solution of NS equations
Link	Computational Fluid Dynamics	Lecture 21 - Pressure-correction approach to the solution of NS equations on a staggered grid; SIMPLE and its family of methods
Link	Computational Fluid Dynamics	Lecture 22 - Need for effici ent solution of linear algebraic equations; Classification of approaches for the solution of linear algebraic equations.
Link	Computational Fluid Dynamics	Lecture 23 - Direct methods for linear algebraic equations; Gaussian elimination method
Link	Computational Fluid Dynamics	Lecture 24 - Gauss-Jordan method; LU decomposition method; TDMA and Thomas algorithm
Link	Computational Fluid Dynamics	Lecture 25 - Basic iterative methods for linear algebraic equations: Description of point -Jacobi, Gauss-Seidel and SOR methods
Link	Computational Fluid Dynamics	Lecture 26 - Convergence analysis of basic iterative schemes; Diagonal dominance condition for convergence; Influence of source terms on the diagonal dominance condition; Rate of convergence
Link	Computational Fluid Dynamics	Lecture 27 - Application to the Laplace equation
Link	Computational Fluid Dynamics	Lecture 28 - Advanced iterative methods: Alternating Direction Implicit Method; Operator splitting
Link	Computational Fluid Dynamics	Lecture 29 - Advanced iterative methods; Strongly Implicit Proc edure; Conjugate gradient method; Multigrid method
Link	Computational Fluid Dynamics	Lecture 30 - Illustration of the Multigrid method for the Laplace equation
Link	Computational Fluid Dynamics	Lecture 31 - Overview of the approach of numerical solution of NS equations for simple domains; Introduction to complexity arising from physics and geometry
Link	Computational Fluid Dynamics	Lecture 32 - Derivation of the energy conservation equation
Link	Computational Fluid Dynamics	Lecture 33 - Derivation of the species conservation equation; dealing with chemical reactions
Link	Computational Fluid Dynamics	Lecture 34 - Turbulence; Characteri stics of turbulent flow; Dealing with fluctuations and the concept of time-averaging
Link	Computational Fluid Dynamics	Lecture 35 - Derivation of the Reynolds -averaged Navier -Stokes equations; identification of the closure problem of turbulence; Boussinesq hypothesis and eddy viscosity
Link	Computational Fluid Dynamics	Lecture 36 - Reynol ds stresses in turbulent flow; Time and length scales of turbulence; Energy cascade; Mixing length model for eddy viscosity
Link	Computational Fluid Dynamics	Lecture 37 - One-equation model for turbulent flow
Link	Computational Fluid Dynamics	Lecture 38 - Two -equation model for turbulent flow; Numerical calculation of turbulent reacting flows
Link	Computational Fluid Dynamics	Lecture 39 - Calculation of near-wall region in turbulent flow; wall function approach; near-wall turbulence models
Link	Computational Fluid Dynamics	Lecture 40 - Need for special methods for dealing with irregular flow geometry; Outline of the Body-fitted grid approach ; Coordinate transformation to a general, 3-D curvilinear system
Link	Computational Fluid Dynamics	Lecture 41 - Transformation of the governing equations; Illustration for the Laplace equation; Appearance and significance of cross -derivative terms; Concepts of structured and unstructured grids.
Link	Computational Fluid Dynamics	Lecture 42 - Finite vol ume method for complicated flow domain; Illustration for the case of flow through a duct of triangular cross -section.
Link	Computational Fluid Dynamics	Lecture 43 - Finite volume method for the general case
Link	Computational Fluid Dynamics	Lecture 44 - Generation of a structured grid for irregular flow domain; Algebraic methods; Elliptic grid generation method
Link	Computational Fluid Dynamics	Lecture 45 - Unstructured grid generation; Domain nodalization; Advancing front method for triangulation
Link	Computational Fluid Dynamics	Lecture 46 - Delaunay triangulation method for unstructured grid generation
Link	Computational Fluid Dynamics	Lecture 47 - Co -located grid approach for irregular geometries; Pressure correction equation for a co -located structured grid; Pressure correction equation for a co-located unstructured grid.
Link	Computational Techniques	Lecture 1 - Introduction
Link	Computational Techniques	Lecture 2 - Computational and Error Analysis
Link	Computational Techniques	Lecture 3 - Linear Equations - Part 1
Link	Computational Techniques	Lecture 4 - Linear Equations - Part 2
Link	Computational Techniques	Lecture 5 - Linear Equations - Part 3
Link	Computational Techniques	Lecture 6 - Linear Equations - Part 4
Link	Computational Techniques	Lecture 7 - Linear Equations - Part 5
Link	Computational Techniques	Lecture 8 - Linear Equations - Part 6
Link	Computational Techniques	Lecture 9 - Non Linear Algebraic Equations - Part 1
Link	Computational Techniques	Lecture 10 - Non Linear Algebraic Equations - Part 2
Link	Computational Techniques	Lecture 11 - Non Linear Algebraic Equations - Part 3
Link	Computational Techniques	Lecture 12 - Non Linear Algebraic Equations - Part 4
Link	Computational Techniques	Lecture 13 - Non Linear Algebraic Equations - Part 5
Link	Computational Techniques	Lecture 14 - Non Linear Algebraic Equations - Part 6
Link	Computational Techniques	Lecture 15 - Regression and Interpolation - Part 1
Link	Computational Techniques	Lecture 16 - Regression and Interpolation - Part 2
Link	Computational Techniques	Lecture 17 - Regression and Interpolation - Part 3
Link	Computational Techniques	Lecture 18 - Regression and Interpolation - Part 4
Link	Computational Techniques	Lecture 19 - Regression and Interpolation - Part 5
Link	Computational Techniques	Lecture 20 - Differentiation and Integration - Part 1
Link	Computational Techniques	Lecture 21 - Differentiation and Integration - Part 2
Link	Computational Techniques	Lecture 22 - Differentiation and Integration - Part 3
Link	Computational Techniques	Lecture 23 - Differentiation and Integration - Part 4
Link	Computational Techniques	Lecture 24 - Differentiation and Integration - Part 5
Link	Computational Techniques	Lecture 25 - Ordinary Differential Equations (initial value problems) - Part 1
Link	Computational Techniques	Lecture 26 - Ordinary Differential Equations (initial value problems) - Part 2
Link	Computational Techniques	Lecture 27 - Ordinary Differential Equations (initial value problems) - Part 3
Link	Computational Techniques	Lecture 28 - Ordinary Differential Equations (initial value problems) - Part 4
Link	Computational Techniques	Lecture 29 - Ordinary Differential Equations (initial value problems) - Part 5
Link	Computational Techniques	Lecture 30 - Ordinary Differential Equations (initial value problems) - Part 6
Link	Computational Techniques	Lecture 31 - Ordinary Differential Equations (initial value problems) - Part 7
Link	Computational Techniques	Lecture 32 - Ordinary Differential Equations (initial value problems) - Part 8
Link	Computational Techniques	Lecture 33 - Ordinary Differential Equations (initial value problems) - Part 9
Link	Computational Techniques	Lecture 34 - Ordinary Differential Equations (boundary value problems) - Part 1
Link	Computational Techniques	Lecture 35 - Ordinary Differential Equations (boundary value problems) - Part 2
Link	Computational Techniques	Lecture 36 - Ordinary Differential Equations (boundary value problems) - Part 3
Link	Computational Techniques	Lecture 37 - Partial Differential Equations - Part 1
Link	Computational Techniques	Lecture 38 - Partial Differential Equations - Part 2
Link	Computational Techniques	Lecture 39 - Partial Differential Equations - Part 3
Link	Computational Techniques	Lecture 40 - Partial Differential Equations - Part 4
Link	Particle Characterization (PG)	Lecture 1 - Introduction: Why study particle characterization?
Link	Particle Characterization (PG)	Lecture 2 - Introduction: Classification of particle characteristics
Link	Particle Characterization (PG)	Lecture 3 - Morphological Characterization: Shape analysis methods
Link	Particle Characterization (PG)	Lecture 4 - Morphological Characterization: Techniques of shape assessment
Link	Particle Characterization (PG)	Lecture 5 - Morphological Characterization: Decision rules
Link	Particle Characterization (PG)	Lecture 6 - Morphological Characterization: Static vs dynamic methods of size analysis
Link	Particle Characterization (PG)	Lecture 7 - Morphological Characterization: Static methods of size analysis
Link	Particle Characterization (PG)	Lecture 8 - Morphological Characterization: Light scattering from spherical particles
Link	Particle Characterization (PG)	Lecture 9 - Morphological Characterization: Particle counters
Link	Particle Characterization (PG)	Lecture 10 - Morphological Characterization: Particle size distributions
Link	Particle Characterization (PG)	Lecture 11 - Morphological Characterization: Acoustic Attenuation Spectroscopy
Link	Particle Characterization (PG)	Lecture 12 - Morphological Characterization: Nano-particle size analysis
Link	Particle Characterization (PG)	Lecture 13 - Structural Characterization
Link	Particle Characterization (PG)	Lecture 14 - Interfacial Characterization
Link	Particle Characterization (PG)	Lecture 15 - Surface Adhesion: Forces
Link	Particle Characterization (PG)	Lecture 16 - Surface Adhesion: Electrostatic & Surface-Tension Forces
Link	Particle Characterization (PG)	Lecture 17 - Surface Adhesion: Adhesion Force Measurement
Link	Particle Characterization (PG)	Lecture 18 - Particle Removal: Methods
Link	Particle Characterization (PG)	Lecture 19 - Particle Removal: Wet Cleaning
Link	Particle Characterization (PG)	Lecture 20 - Particle Cohesion: Forces
Link	Particle Characterization (PG)	Lecture 21 - Particle Cohesion: Flowability Implications
Link	Particle Characterization (PG)	Lecture 22 - Transport Properties: Diffusion & Electrostatic Field Effects
Link	Particle Characterization (PG)	Lecture 23 - Transport Properties: Drag & Inertia
Link	Particle Characterization (PG)	Lecture 24 - Transport Properties: Deposition Fluxes & Rates
Link	Particle Characterization (PG)	Lecture 25 - Transport Properties: Illustrative Application
Link	Particle Characterization (PG)	Lecture 26 - Chemical & Compositional Characterization: Reactivity
Link	Particle Characterization (PG)	Lecture 27 - Chemical & Compositional Characterization: Analytical Methods
Link	Particle Characterization (PG)	Lecture 28 - Chemical & Compositional Characterization: XRD & AFM
Link	Particle Characterization (PG)	Lecture 29 - Nano-particle Characterization: Bottom-Up Synthesis Methods
Link	Particle Characterization (PG)	Lecture 30 - Nano-particle Characterization: Top-Down Synthesis Methods
Link	Particle Characterization (PG)	Lecture 31 - Nano-particle Characterization: Dispersion
Link	Particle Characterization (PG)	Lecture 32 - Nano-particle Characterization: Properties & Techniques
Link	Particle Characterization (PG)	Lecture 33 - Practical Relevance of Particle Characterization: Nano-Fluids
Link	Particle Characterization (PG)	Lecture 34 - Practical Relevance of Particle Characterization: Filtration
Link	Particle Characterization (PG)	Lecture 35 - Practical Relevance of Particle Characterization: Cleanrooms
Link	Particle Characterization (PG)	Lecture 36 - Practical Relevance of Particle Characterization: High-Technology Manufacturing
Link	Particle Characterization (PG)	Lecture 37 - Practical Relevance of Particle Characterization: Explosivity
Link	Particle Characterization (PG)	Lecture 38 - Practical Relevance of Particle Characterization: Environment & Human Health
Link	Particle Characterization (PG)	Lecture 39 - Practical Relevance of Particle Characterization: Other Applications
Link	Particle Characterization (PG)	Lecture 40 - Summary
Link	Statistics for Experimentalists	Lecture 1 - Introduction
Link	Statistics for Experimentalists	Lecture 2 - Random Variables
Link	Statistics for Experimentalists	Lecture 3 - Discrete Probability Distributions
Link	Statistics for Experimentalists	Lecture 4 - Example Set - I
Link	Statistics for Experimentalists	Lecture 5 - Continuous probability distributions
Link	Statistics for Experimentalists	Lecture 6 - Normal probability distribution
Link	Statistics for Experimentalists	Lecture 7 - Exploratory Data Analysis - Part A
Link	Statistics for Experimentalists	Lecture 8 - Exploratory Data Analysis - Part B
Link	Statistics for Experimentalists	Lecture 9 - Example Set - II
Link	Statistics for Experimentalists	Lecture 10 - Example Set - III
Link	Statistics for Experimentalists	Lecture 11 - Random samples: Sampling distribution of the mean (Part A)
Link	Statistics for Experimentalists	Lecture 12 - Random samples: Sampling distribution of the mean (Part B)
Link	Statistics for Experimentalists	Lecture 13 - Point Estimation
Link	Statistics for Experimentalists	Lecture 14 - Sampling distributions and the Central Limit Theorem
Link	Statistics for Experimentalists	Lecture 15 - Example Set - IV Part A
Link	Statistics for Experimentalists	Lecture 16 - Estimation of Population Parameters Using Moments
Link	Statistics for Experimentalists	Lecture 17 - Confidence Intervals (Part A)
Link	Statistics for Experimentalists	Lecture 18 - Confidence Intervals (Part B)
Link	Statistics for Experimentalists	Lecture 19 - The T-distribution
Link	Statistics for Experimentalists	Lecture 20 - Chi-square distribution
Link	Statistics for Experimentalists	Lecture 21 - F-Distribution
Link	Statistics for Experimentalists	Lecture 22 - Example Set - V
Link	Statistics for Experimentalists	Lecture 23 - Hypothesis Testing - Part A
Link	Statistics for Experimentalists	Lecture 24 - Hypothesis Testing - Part B
Link	Statistics for Experimentalists	Lecture 25 - Hypothesis Testing - Part C
Link	Statistics for Experimentalists	Lecture 26 - Analysis of Experiments involving Single Factor - Part A
Link	Statistics for Experimentalists	Lecture 27 - Analysis of Experiments involving Single Factor - Part B
Link	Statistics for Experimentalists	Lecture 28 - Blocking and Randomization
Link	Statistics for Experimentalists	Lecture 29 - Example Set - VI - Part A
Link	Statistics for Experimentalists	Lecture 30 - Example Set - VI - Part B
Link	Statistics for Experimentalists	Lecture 31 - Factorial Design of Experiments - Part A
Link	Statistics for Experimentalists	Lecture 32 - Factorial Design of Experiments - Part B: 22 Factorial Design
Link	Statistics for Experimentalists	Lecture 33 - Fractional Factorial Design - Part A
Link	Statistics for Experimentalists	Lecture 34 - Fractional Factorial Design - Part B
Link	Statistics for Experimentalists	Lecture 35 - Factorial Design of Experiments: Example Set (Part A)
Link	Statistics for Experimentalists	Lecture 36 - Factorial Design of Experiments: Example Set (Part B)
Link	Statistics for Experimentalists	Lecture 37 - Factorial Design of Experiments: Example Set (Part C)
Link	Statistics for Experimentalists	Lecture 38 - Regression Analysis: Part A
Link	Statistics for Experimentalists	Lecture 39 - Regression Analysis: Part B
Link	Statistics for Experimentalists	Lecture 40 - Hypothesis Testing in Linear Regression
Link	Statistics for Experimentalists	Lecture 41 - Discussion on Regression Output
Link	Statistics for Experimentalists	Lecture 42 - Regression Analysis: Example Set 8
Link	Statistics for Experimentalists	Lecture 43 - Regression Analysis: Example Set 8 (Continued...)
Link	Statistics for Experimentalists	Lecture 44 - Regression Analysis: Example Set 8 (Continued...)
Link	Statistics for Experimentalists	Lecture 45 - Orthogonal Model Fitting Concepts - Part A
Link	Statistics for Experimentalists	Lecture 46 - Orthogonal Model Fitting Concepts - Part B
Link	Statistics for Experimentalists	Lecture 47 - Experimental Design Strategies - A
Link	Statistics for Experimentalists	Lecture 48 - Experimental Design Strategies - B
Link	Statistics for Experimentalists	Lecture 49 - Experimental Design Strategies - C
Link	Statistics for Experimentalists	Lecture 50 - Response Surface Methodology - A
Link	Statistics for Experimentalists	Lecture 51 - Response Surface Methodology - B
Link	Statistics for Experimentalists	Lecture 52 - Optimal Designs - Part A
Link	Statistics for Experimentalists	Lecture 53 - Optimal Designs - Part B
Link	Statistics for Experimentalists	Lecture 54 - Statistics for Experimentalists - Summary Part A
Link	Statistics for Experimentalists	Lecture 55 - Statistics for Experimentalists - Summary Part B
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 1 - Introduction and overview of the course: Multiphase flows
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 2 - Stratified flow in a micro channel: Velocity profiles
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 3 - Stratified flow in a micro channel: Effects of physical parameters
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 4 - Flow regimes in microchannels: Modeling and Experiments
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 5 - Scaling Analysis: Introduction
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 6 - Scaling Analysis: Worked Examples
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 7 - Interfacial tension and its role in Multiphase flows
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 8 - Eulerian and Lagrangian approaches
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 9 - Reynolds Transport Theorem and the Equation of Continuity
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 10 - Derivation of Navier-Stokes equation
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 11 - Vector operations in general orthogonal coordinates: Grad., Div., Lapacian
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 12 - Normal and shear stresses on arbitrary surfaces: Force balance
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 13 - Normal and shear stresses on arbitrary surfaces: Stress Tensor formulation
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 14 - Stresses on deforming surfaces: Introduction to Perturbation Theory
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 15 - Pulsatile flow: Analytical solution
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 16 - Pulsatile flow: Analytical solution and perturbation solution for Rw 1
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 17 - Pulsatile flow: Perturbation solution for Rw 1
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 18 - Viscous heating: Apparent viscosity in a viscometer
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 19 - Domain perturbation methods: Flow between wavy walls
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 20 - Flow between wavy walls: Velocity profile
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 21 - Introduction to stability of dynamical systems: ODEs
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 22 - Stability of distributed systems (PDEs): reaction diffusion example
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 23 - Stability of a reaction-diffusion system (Continued...)
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 24 - Rayleigh-Benard convection: Physics and governing equations
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 25 - Rayleigh-Benard convection: Linear stability analysis - Part 1
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 26 - Rayleigh-Benard convection: Linear stability analysis - Part 2
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 27 - Rayleigh-Benard convection: Linear stability analysis - Part 3
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 28 - Rayleigh Benard convection: Discussion of results
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 29 - Rayleigh-Taylor ‘heavy over light’ instability
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 30 - Rayleigh-Taylor instability (Continued...)
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 31 - Capillary jet instability: Problem formulation
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 32 - Capillary jet instability: Linear stability analysis
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 33 - Capillary jet instability: Rayleigh’s Work Principle
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 34 - Tutorial Session: Solution of Assignment 4 on linear stability
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 35 - Turing patterns: Instability in reaction-diffusion systems
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 36 - Turing patterns: Results
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 37 - Marangoni convection: Generalised tangential and normal stress boundary conditions
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 38 - Marangoni convection: Stability analysis
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 39 - Flow in a circular curved channel: Governing equations and scaling
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 40 - Flow in a circular curved channel: Solution by regular perturbation
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 41 - Stability of flow through curved channels: Problem formulation
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 42 - Stability of flow through curved channels: Numerical calculation
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 43 - Viscous Fingering: Darcy’s law
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 44 - Viscous Fingering: Stability analysis
Link	Multiphase flows:Analytical solutions and Stability Analysis	Lecture 45 - Shallow Cavity flows
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 1 - Introduction - Lecture 1.1 A
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 2 - Introduction - Lecture 1.1 B
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 3 - Introduction - Lecture 1.2 A
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 4 - Introduction - Lecture 1.2 B
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 5 - Basic Definitions and concepts - Lecture 2.1 (Basic Definitions and concepts - Part I)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 6 - Basic Definitions and concepts - Lecture 2.2 (Basic Definitions and concepts - Part II)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 7 - Basic Definitions and concepts - Lecture 2.3 (Basic Definitions and concepts - Part III)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 8 - A review of Fourier transforms - Lecture 3.1 (Continuous time Fourier series)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 9 - A review of Fourier transforms - Lecture 3.2 (Continuous time Fourier transform)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 10 - A review of Fourier transforms - Lecture 3.3 (Discrete time Fourier series)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 11 - A review of Fourier transforms - Lecture 3.4 (Discrete time Fourier transform)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 12 - A review of Fourier transforms - Lecture 3.5 (Properties of Fourier transforms)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 13 - A review of Fourier transforms - Lecture 3.6 (Discrete Fourier transform)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 14 - A review of Fourier transforms - MATLAB demo of Fourier transform and periodogram
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 15 - Duration and Bandwidth - Duration and Bandwidth
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 16 - Duration and Bandwidth - Bandwidth equation and Instantaneous frequency
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 17 - Duration and Bandwidth - Instantaneous frequency and analytic signals
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 18 - Duration and Bandwidth - Duration-Bandwidth principle
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 19 - Duration and Bandwidth - Requirements of time-frequency anlysis techniques
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 20 - Duration and Bandwidth - Requirements of time-frequency analysis and techniques
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 21 - Short-time Fourier transform - Short-time Fourier transform
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 22 - Short-time Fourier transform - Auxillary (MATLAB demonstration)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 23 - Short-time Fourier transform - Properties of STFT
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 24 - Practical aspects of STFT
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 25 - Closing Remarks
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 26 - Wigner-Ville Distributions
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 27 - Properties of WVD
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 28 - Properties of WVD 2
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 29 - Discrete WVD
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 30 - Pseudo and Smoothed WVD
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 31 - Cohens class and smoothed WVD
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 32 - Cohens class and smoothed WVD
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 33 - Cohens class and Ambiguity functions
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 34 - Affine class and closing remarks
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 35 - Continuous Wavelet Transform
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 36 - Continuous Wavelet Transforms
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 37 - Scale to Frequency
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 38 - Computational aspects of CWT
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 39 - Scalogram and MATLAB demonstration
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 40 - Scalogram and MATLAB demonstration
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 41 - Scaling function
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 42 - Scaling Function
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 43 - Wavelets
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 44 - Wavelets
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 45 - Applications of CWT
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 46 - Applications of CWT
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 47 - Discrete Wavelet Transform
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 48 - Discrete Wavelet Transform.
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 49 - Orthogonal scaling function bases and MRA
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 50 - Orthogonal scaling function bases and MRA.
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 51 - Wavelet Filters and Fast DWT Algorithm
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 52 - Wavelet Filters and Fast DWT Algorithm (Continued...)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 53 - Wavelet Filters and Fast DWT Algorithm (Continued...)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 54 - Wavelets for DWT
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 55 - Wavelets for DWT (Continued...)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 56 - Wavelets for DWT (Continued...)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 57 - DWT computation
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 58 - DWT computation (Continued...)
Link	NOC:Introduction to Time-Frequency Analysis and Wavelet Transforms	Lecture 59 - DWT computation (Continued...)
Link	Chemical Engineering Principles of CVD Processes	Lecture 1 - Introduction
Link	Chemical Engineering Principles of CVD Processes	Lecture 2 - CVD Reactor and Process Design Fundamentals
Link	Chemical Engineering Principles of CVD Processes	Lecture 3 - Overview of CVD Process Fundamentals
Link	Chemical Engineering Principles of CVD Processes	Lecture 4 - Basics of Chemical Equilibrium Calculations and Flow Dynamics
Link	Chemical Engineering Principles of CVD Processes	Lecture 5 - Introduction to CVD Films
Link	Chemical Engineering Principles of CVD Processes	Lecture 6 - Film Structure and Properties
Link	Chemical Engineering Principles of CVD Processes	Lecture 7 - Pressure Effects on CVD Processes
Link	Chemical Engineering Principles of CVD Processes	Lecture 8 - CVD of Metals
Link	Chemical Engineering Principles of CVD Processes	Lecture 9 - CVD of Coatings
Link	Chemical Engineering Principles of CVD Processes	Lecture 10 - CVD Film Property Measurements
Link	Chemical Engineering Principles of CVD Processes	Lecture 11 - CVD Film Property Measurements: Qualitative and Quantitative
Link	Chemical Engineering Principles of CVD Processes	Lecture 12 - CVD in Tungsten Filament Lamps
Link	Chemical Engineering Principles of CVD Processes	Lecture 13 - CVD in Tungsten Filament Lamps: Design Aspects
Link	Chemical Engineering Principles of CVD Processes	Lecture 14 - CVD in Hot Corrosion
Link	Chemical Engineering Principles of CVD Processes	Lecture 15 - CVD Transport Phenomena: Conservation Equations
Link	Chemical Engineering Principles of CVD Processes	Lecture 16 - CVD Transport Phenomena: Constitutive Laws
Link	Chemical Engineering Principles of CVD Processes	Lecture 17 - CVD Transport Phenomena: Mass Transfer Mechanisms
Link	Chemical Engineering Principles of CVD Processes	Lecture 18 - CVD Transport Phenomena: Mass Transfer Analogy Condition (MTAC)
Link	Chemical Engineering Principles of CVD Processes	Lecture 19 - CVD Transport Phenomena: Effect of Homogeneous Reactions on MTAC
Link	Chemical Engineering Principles of CVD Processes	Lecture 20 - CVD Applications: Hot Filament CVD (HFCVD)
Link	Chemical Engineering Principles of CVD Processes	Lecture 21 - CVD Applications: Aerosol CVD (ACVD)
Link	Chemical Engineering Principles of CVD Processes	Lecture 22 - CVD Applications: CVD of Silicon
Link	Chemical Engineering Principles of CVD Processes	Lecture 23 - CVD Applications: CVD in Free-Molecular Flow Regime (FMFR)
Link	Chemical Engineering Principles of CVD Processes	Lecture 24 - CVD Applications: CVD of nano-Structured Films
Link	Chemical Engineering Principles of CVD Processes	Lecture 25 - CVD Overview
Link	Chemical Engineering Principles of CVD Processes	Lecture 26 - Review of CVD Basics: Part-I (PDF)
Link	Chemical Engineering Principles of CVD Processes	Lecture 27 - Review of CVD Basics: Part-II (PDF)
Link	Chemical Engineering Principles of CVD Processes	Lecture 28 - CVD Question Bank (PDF)
Link	Chemical Engineering Principles of CVD Processes	Lecture 29 - Basics of Nano-Structured Material Synthesis: Part-I
Link	Chemical Engineering Principles of CVD Processes	Lecture 30 - Basics of Nano-Structured Material Synthesis: Part-II
Link	Chemical Engineering Principles of CVD Processes	Lecture 31 - Undesirable CVD: Bulb-Blackening (Adobe Presenter)
Link	Chemical Engineering Principles of CVD Processes	Lecture 32 - Undesirable CVD: Moolten Salt Deposition in Combustion Systems (Adobe Presenter)
Link	Chemical Engineering Principles of CVD Processes	Lecture 33 - Undesirable CVD: Hot Corrosion (Adobe Presenter)
Link	Chemical Engineering Principles of CVD Processes	Lecture 34 - Multi-component Transport Fundamentals: Assumptions and Control Volumes (Adobe Presenter)
Link	Chemical Engineering Principles of CVD Processes	Lecture 35 - Multi-component Transport Fundamentals: Mass Conservation Equations (Adobe Presenter)
Link	Chemical Engineering Principles of CVD Processes	Lecture 36 - Multi-component Transport Fundamentals: Momentum and Energy Conservation (Adobe Presenter)
Link	Chemical Engineering Principles of CVD Processes	Lecture 37 - Multi-component Transport Fundamentals: Entropy conservation (Adobe Presenter)
Link	Chemical Engineering Principles of CVD Processes	Lecture 38 - Multi-component Transport Fundamentals: Constitutive Laws for Mass and Momentum (Adobe Presenter)
Link	Chemical Engineering Principles of CVD Processes	Lecture 39 - Multi-component Transport Fundamentals: Constitutive Laws for Energy and Entropy (Adobe Presenter)
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 1 - Motivation and Introduction - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 2 - Motivation and Introduction - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 3 - What is Chemical Engineering - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 4 - What is Chemical Engineering - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 5 - What is Chemical Reaction Engineering - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 6 - What is Chemical Reaction Engineering - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 7 - Homogeneous and Heterogeneous Reactions - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 8 - Homogeneous and Heterogeneous Reactions - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 9 - Basics of Kinetics and Contacting
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 10 - Design of Batch reactors - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 11 - Design of Batch reactors - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 12 - Basics of Plug Flow Reactor - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 13 - Basics of Plug Flow Reactor - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 14 - Design of Plug Flow Reactors - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 15 - Design of Plug Flow Reactors - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 16 - Basics of Mixed Flow Reactors
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 17 - Design of Mixed Flow Reactors
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 18 - Basics of Kinetics
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 19 - Kinetics of Heterogeneous reactions - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 20 - Kinetics of Heterogeneous reactions - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 21 - Kinetics of Heterogeneous reactions - Part III
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 22 - Kinetics of Homogeneous reactions
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 23 - Reaction rate for Homogeneous reactions
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 24 - Gas Phase Homogeneous reactions
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 25 - (Continued...) And later Reactor Design of PFR
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 26 - Reactor Design for MFR and Combination of reactors
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 27 - PFR and MFR in series.
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 28 - Unsteady state MFR and PFR
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 29 - Recycle Reactors
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 30 - Recycle Reactors (Autocatalytic reactions) - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 31 - Recycle Reactors (Autocatalytic reactions) - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 32 - Multiple Reactions - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 33 - Multiple Reactions - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 34 - Multiple Reactions - Part III
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 35 - Multiple Reactions - Part IV
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 36 - Multiple Reactions - Part V
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 37 - Multiple Reactions - Part VI
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 38 - Non-Isothermal Reactors - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 39 - Non-Isothermal Reactors - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 40 - Non-Isothermal Reactors (Graphical Design)
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 41 - Non-Isothermal Reactors contd. & Adiabatic Reactors
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 42 - Non-Isothermal Reactors (Graphical Design) (Continued...)
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 43 - Non-Isothermal Batch Reactors
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 44 - Non-isothermal Plug Flow Reactors - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 45 - Non-isothermal Plug Flow Reactors - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 46 - Adiabatic Plug Flow Reactors
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 47 - Non-isothermal Mixed Flow Reactors
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 48 - Non-isothermal Mixed Flow Reactors (Continued...) (Multiple steady states) - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 49 - Non-isothermal Mixed Flow Reactors (Continued...) (Multiple steady states) - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 50 - Non-Ideal Flow and Residence Time Distributions (RTD) basics - Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 51 - Non-Ideal Flow and Residence Time Distributions (RTD) basics - Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 52 - RTD for various reactors (Continued...) Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 53 - RTD for various reactors (Continued...) Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 54 - Diagnosing the ills of equipments and Various RTD Models
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 55 - Dispersion Model
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 56 - Dispersion with reaction Model and Tanks in Series Model
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 57 - Multi-parameter model (MFR with dead space and bypass)
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 58 - Direct use of RTD to predict conversion (Macro and Micro-fluid as well as Macro & Micro-mixing Concept) Part I
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 59 - Direct use of RTD to predict conversion (Macro and Micro-fluid as well as Macro & Micro-mixing Concept) Part II
Link	Chemical Reaction Engineering 1 (Homogeneous Reactors)	Lecture 60 - Direct use of RTD to predict conversion (Macro and Micro-fluid as well as Macro & Micro-mixing Concept) Part III
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 1 - Introduction to Kinetics (Gas solid non-catalytic reaction)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 2 - Intro to Kinetics (Continued...) for catalytic reactions in different reactors
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 3 - Heterogeneous rate of reactions and different types of kinetic models for non-catalytic reactions
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 4 - Basics of Kinetics of type A & B reactions (Shrinking core model & Porous particle homogeneous model)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 5 - Shrinking Core Model (Continued...)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 6 - Shrinking Core Model (Continued...)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 7 - (Continued...) & Proof of Pseudo steady state assumption
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 8 - Shrinking core model (Continued...) for type D reactions
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 9 - Shrinking core model (Continued...) for type D reactions (Continued...)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 10 - Reactors, Homogeneous reaction model, Design of non-catalytic gas solid reactors
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 11 - Design of non-catalytic gas solid reactors (Continued...)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 12 - Design of non-catalytic gas solid reactors (Continued...)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 13 - Design equation for MF of solids, uniform gas composition, const. single particle size, Shrinking core model.
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 14 - Design equation for MF of solids, mixture of particles for different sizes but unchanging size, uniform gas composition, SCM
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 15 - Design equation for MF of solids with elutriation, mixture of particles of different size, uniform gas composition, SCM
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 16 - General Performance equation for non-catalytic gas solid reactions
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 17 - Catalytic reactions (LHHW Kinetic model)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 18 - LHHW Kinetic model (Continued...) - Part I
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 19 - LHHW Kinetic model (Continued...) - Part II
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 20 - Industrially important catalytic reaction models
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 21 - Inter and Intraphase effectiveness fator
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 22 - Interface effectiveness factor & Generalized nonisothermal effectiveness factor for external mass transfer step
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 23 - Generalized nonisothermal effectiveness factor for external mass transfer step (Continued...)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 24 - Mass transfer correlations for various reactors
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 25 - Isothermal intraphase effectiveness factor - Part I
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 26 - Isothermal intraphase effectiveness factor - Part II
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 27 - Non-isothermal intraphase effectiveness factor
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 28 - Inter and Intraphase effectiveness factor (Continued...)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 29 - Inter and Intraphase Mass transfer
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 30 - Packed (fixed) bed catalytic reactor design
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 31 - Graphical design of Fixed bed reactors
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 32 - Packed Bed Design (Continued...)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 33 - Design equations for Packed bed reactor design
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 34 - Conservative Equations for Packed bed Reactor design
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 35 - Problem solving session
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 36 - Fluidized Bed Reactor Design - Part I
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 37 - Fluidized Bed Reactor Design - Part II
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 38 - Fluidized Bed Reactor Design - Part III
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 39 - Fluidized Bed Reactor Design - Part IV
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 40 - Continued... (Fluidized bed reactor Models)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 41 - Continued... (Davidson Harrison model and Kunii Levenspiel model)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 42 - Continued... (Kunii Levenspiel Model)
Link	Chemical Reaction Engineering 2 (Heterogeneous Reactors)	Lecture 43 - Slurry Reactor Design
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 1 - Course Introduction
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 2 - Basics of Programming using MATLAB
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 3 - Array Operations in MATLAB
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 4 - Loops and Execution Control
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 5 - Tutorial: Using Arrays
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 6 - MATLAB Files -- Scripts and Functions
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 7 - Plotting and Output
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 8 - How to submit MATLAB Assignment
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 9 - Errors in Numerical Computation
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 10 - Truncation Errors and Taylors Series
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 11 - Round-Off Errors; and Iterative Methods
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 12 - Step-wise Methods and Error Propagation
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 13 - How to get MATLAB Online access (for all enrolled students of this course)
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 14 - Differentiation in Single Variable
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 15 - Higher Order Differentiation Formulae
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 16 - Partial Differentials (Bonus)
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 17 - Numerical Integration
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 18 - Multiple Applications of Integration Formulae
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 19 - In-Build MATLAB Integration Functions
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 20 - Basics of Linear Algebra
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 21 - Gauss Elimination and Back-Substitution
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 22 - LU Decomposition and Partial Pivoting
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 23 - Gauss Siedel Method
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 24 - (Tutorial)
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 25 - Tri-Diagonal Matrix Algorithm
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 26 - Nonlinear Equations in Single Variable
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 27 - Using MATLAB command fzero
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 28 - Fixed Point Iteration in Single Variable
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 29 - Newton-Raphson (single variable)
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 30 - Using MATLAB command fsolve (multi-variable)
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 31 - Newton-Raphson (multi Variable)
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 32 - Introduction
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 33 - Linear Least Squares Regression
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 34 - Nonlinear and Functional Regression
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 35 - Interpolation Functions in MATLAB
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 36 - Introduction and Euler\'s Method
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 37 - Runge-Kutta (RK-2) method
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 38 - MATLAB ode45 algorithm
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 39 - Higher order Runge-Kutta Methods
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 40 - Error Analysis
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 41 - Multi-Variable ODE
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 42 - Stiff Systems & Solution using ode15s
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 43 - Method of Lines for transient PDEs
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 44 - A Final Example
Link	NOC:MATLAB Programming for Numerical Computation	Lecture 45 - Tutorial: How to do linear and nonlinear regression
Link	NOC:Computational Fluid Dynamics	Lecture 1 - Motivation
Link	NOC:Computational Fluid Dynamics	Lecture 2 - Flow in a rectangular duct: Problem formulation
Link	NOC:Computational Fluid Dynamics	Lecture 3 - Flow in a rectangular duct: Discretiztion of flow domain
Link	NOC:Computational Fluid Dynamics	Lecture 4 - Tutorial 1: Converting PDE to algebraic equation using FD approximation
Link	NOC:Computational Fluid Dynamics	Lecture 5 - Tutorial 1 (Continued...) Solution for algebraic equations using Gauss- Seidel Method
Link	NOC:Computational Fluid Dynamics	Lecture 6 - Flow in a triangular duct: Problem formulation
Link	NOC:Computational Fluid Dynamics	Lecture 7 - Flow in a triangular duct: Discretiztion of flow domain
Link	NOC:Computational Fluid Dynamics	Lecture 8 - Tutorial 2: Converting PDE to algebraic equation using Finite Volume method
Link	NOC:Computational Fluid Dynamics	Lecture 9 - Tutorial 2 (Continued...) Description of FV method and solution using G-S Method
Link	NOC:Computational Fluid Dynamics	Lecture 10 - Effect of grid spacing & upcoming course outline
Link	NOC:Computational Fluid Dynamics	Lecture 11 - Mass conservation equations
Link	NOC:Computational Fluid Dynamics	Lecture 12 - Momentum conservation equations
Link	NOC:Computational Fluid Dynamics	Lecture 13 - Forces acting on control volume
Link	NOC:Computational Fluid Dynamics	Lecture 14 - Kinematics of deformation in fluid flow
Link	NOC:Computational Fluid Dynamics	Lecture 15 - Equations governing fluid flow in incompressible fluid
Link	NOC:Computational Fluid Dynamics	Lecture 16 - Navier-Stokes equation for simple cases of flow
Link	NOC:Computational Fluid Dynamics	Lecture 17 - Energy conservation equations
Link	NOC:Computational Fluid Dynamics	Lecture 18 - Practical cases of fluid flow with heat transfer in CFD point of view
Link	NOC:Computational Fluid Dynamics	Lecture 19 - Practical cases of fluid flow with mass transfer in CFD point of view
Link	NOC:Computational Fluid Dynamics	Lecture 20 - Equations governing fluid flow with chemical reactions
Link	NOC:Computational Fluid Dynamics	Lecture 21 - Concept of wellposedness of mathematical problems
Link	NOC:Computational Fluid Dynamics	Lecture 22 - Introduction to finite difference methods
Link	NOC:Computational Fluid Dynamics	Lecture 23 - Finite difference approximation on an uniform mesh
Link	NOC:Computational Fluid Dynamics	Lecture 24 - Higher order and mixed derivatives
Link	NOC:Computational Fluid Dynamics	Lecture 25 - Solution of Poisson equation in rectangular duct-Turorial
Link	NOC:Computational Fluid Dynamics	Lecture 26 - Discretization of time domain
Link	NOC:Computational Fluid Dynamics	Lecture 27 - FD approx. on a non-uniform mesh and need of analysis of obtained discretization
Link	NOC:Computational Fluid Dynamics	Lecture 28 - Need for the analysis of discretized equation
Link	NOC:Computational Fluid Dynamics	Lecture 29 - Properties of Numerical Schemes: Accuracy, Conservation property, Boundedness, Consistency, Stability and Convergence
Link	NOC:Computational Fluid Dynamics	Lecture 30 - Properties of Numerical Schemes: Stability analysis
Link	NOC:Computational Fluid Dynamics	Lecture 31 - Tutorial on Stability Analysis
Link	NOC:Computational Fluid Dynamics	Lecture 32 - Analysis of Generic 1-d scalar transport equation
Link	NOC:Computational Fluid Dynamics	Lecture 33 - Introduction to the solution of coupled N-S equations
Link	NOC:Computational Fluid Dynamics	Lecture 34 - N-S equation in compressible flow- Mac Cormack Scheme
Link	NOC:Computational Fluid Dynamics	Lecture 35 - Stability limits of Mac-Cormack Scheme and the intro to Beam-Warming Scheme
Link	NOC:Computational Fluid Dynamics	Lecture 36 - Implicit Beam-Warming Scheme
Link	NOC:Computational Fluid Dynamics	Lecture 37 - Compressible flow to Incompressible flow
Link	NOC:Computational Fluid Dynamics	Lecture 38 - Solution of coupled equations: Incompressible flow
Link	NOC:Computational Fluid Dynamics	Lecture 39 - Artificial compressiblity method, Stream function-vorticity method
Link	NOC:Computational Fluid Dynamics	Lecture 40 - Pressure equation method, Staggered grid system
Link	NOC:Computational Fluid Dynamics	Lecture 41 - Pressure Correction Method
Link	NOC:Computational Fluid Dynamics	Lecture 42 - Tutorial on Pressure Correction Method
Link	NOC:Computational Fluid Dynamics	Lecture 43 - Tutorial on Pressure Correction Method (Continued...)
Link	NOC:Computational Fluid Dynamics	Lecture 44 - Introduction to the basic numerical methods
Link	NOC:Computational Fluid Dynamics	Lecture 45 - Direct Methods: solution of the system of algebraic equations
Link	NOC:Computational Fluid Dynamics	Lecture 46 - Tri-diagonal Matrix Algorithm: Derivation
Link	NOC:Computational Fluid Dynamics	Lecture 47 - TDMA and other iterative methods
Link	NOC:Computational Fluid Dynamics	Lecture 48 - Recap of basic iterative methods.
Link	NOC:Computational Fluid Dynamics	Lecture 49 - Convergence analysis of basic iterative methods
Link	NOC:Computational Fluid Dynamics	Lecture 50 - Successive Over Relaxation (SOR) method
Link	NOC:Computational Fluid Dynamics	Lecture 51 - Alternating Direction Implicit (ADI) method
Link	NOC:Computational Fluid Dynamics	Lecture 52 - Strongly Implicit Procedure (ILU) method
Link	NOC:Computational Fluid Dynamics	Lecture 53 - Multigrid method
Link	NOC:Computational Fluid Dynamics	Lecture 54 - Body Fitted Grid Approach
Link	NOC:Computational Fluid Dynamics	Lecture 55 - Formulation Of Finite Volume Method
Link	NOC:Computational Fluid Dynamics	Lecture 56 - Methods For Unstructured Grid Generation
Link	NOC:Computational Fluid Dynamics	Lecture 57 - Triangulation: The Advancing Front Method
Link	NOC:Computational Fluid Dynamics	Lecture 58 - The Advancing Front Method continuation
Link	NOC:Computational Fluid Dynamics	Lecture 59 - Time and length scale of turbulance
Link	NOC:Computational Fluid Dynamics	Lecture 60 - The turbulent closure problem
Link	NOC:Computational Fluid Dynamics	Lecture 61 - The generic formulation for turbulence
Link	NOC:Computational Fluid Dynamics	Lecture 62 - More generic formulation and summary
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 1 - Motivation
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 2 - Probability and statistics: Review - Part 1
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 3 - Probability and Statistics: Review - Part 2
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 4 - R Tutorial 1
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 5 - Statistics for Hypothesis Testing - Part 1
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 6 - Statistics for Hypothesis Testing - Part 2
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 7 - Statistics for sample mean
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 8 - Statistics for Variance and Proportion
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 9 - Type I and Type II errors
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 10 - p value
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 11 - Hypothesis testing of means
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 12 - Hypothesis testing of variance and proportions
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 13 - Confidence interval construction
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 14 - Hypothesis testing using confidence interval
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 15 - Hypothesis testing of correlation
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 16 - Statistic for linear regression
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 17 - Hypothesis testing in linear regression
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 18 - Power of hypothesis test
Link	NOC:Introduction to Statistical Hypothesis Testing	Lecture 19 - Factors affecting hypothesis test
Link	NOC:Applied Time-Series Analysis	Lecture 1 - Lecture 1 - Part 1 - Motivation and Overview 1
Link	NOC:Applied Time-Series Analysis	Lecture 2 - Lecture 1 - Part 2 - Motivation and Overview 2
Link	NOC:Applied Time-Series Analysis	Lecture 3 - Lecture 2 - Part 1 - Motivation and Overview 3
Link	NOC:Applied Time-Series Analysis	Lecture 4 - Lecture 2 - Part 2 - Motivation and Overview 4
Link	NOC:Applied Time-Series Analysis	Lecture 5 - Lecture 3 - Part 1 - Motivation and Overview 5
Link	NOC:Applied Time-Series Analysis	Lecture 6 - Lecture 3 - Part 2 - Motivation and Overview 6
Link	NOC:Applied Time-Series Analysis	Lecture 7 - Lecture 4 - Part 1 - Probability and Statistics Review 1A
Link	NOC:Applied Time-Series Analysis	Lecture 8 - Lecture 4 - Part 2 - Probability and Statistics Review 1B
Link	NOC:Applied Time-Series Analysis	Lecture 9 - Lecture 5 - Part 1 - Probability and Statistics Review 1C
Link	NOC:Applied Time-Series Analysis	Lecture 10 - Lecture 5 - Part 2 - Probability and Statistics Review 1D
Link	NOC:Applied Time-Series Analysis	Lecture 11 - Lecture 6 - Part 1 - Probability and Statistics Review 2A
Link	NOC:Applied Time-Series Analysis	Lecture 12 - Lecture 6 - Part 2 - Probability and Statistics Review 2B
Link	NOC:Applied Time-Series Analysis	Lecture 13 - Lecture 6 - Part 3 - Probability and Statistics Review 2C
Link	NOC:Applied Time-Series Analysis	Lecture 14 - Lecture 7 - Part 1 - Probability and Statistics Review 2D
Link	NOC:Applied Time-Series Analysis	Lecture 15 - Lecture 7 - Part 2 - Probability and Statistics Review 2E
Link	NOC:Applied Time-Series Analysis	Lecture 16 - Lecture 7 - Part 3 - Probability and Statistics Review 2F
Link	NOC:Applied Time-Series Analysis	Lecture 17 - Lecture 8 - Part 1 - Probability and Statistics Review 2G (with R Demonstration)
Link	NOC:Applied Time-Series Analysis	Lecture 18 - Lecture 8 - Part 2 - Probability and Statistics Review 2H (with R Demonstration)
Link	NOC:Applied Time-Series Analysis	Lecture 19 - Lecture 9 - Part 1 - Probability and Statistics Review 2I
Link	NOC:Applied Time-Series Analysis	Lecture 20 - Lecture 9 - Part 2 - Probability and Statistics Review 2J
Link	NOC:Applied Time-Series Analysis	Lecture 21 - Lecture 9 - Part 3 - Introduction to Random Processes 1
Link	NOC:Applied Time-Series Analysis	Lecture 22 - Lecture 10 - Part 1 - Introduction to Random Processes 2
Link	NOC:Applied Time-Series Analysis	Lecture 23 - Lecture 10 - Part 2 - Introduction to Random Processes 3
Link	NOC:Applied Time-Series Analysis	Lecture 24 - Lecture 11 - Part 1 - Introduction to Random Processes 4
Link	NOC:Applied Time-Series Analysis	Lecture 25 - Lecture 11 - Part 2 - Introduction to Random Processes 5
Link	NOC:Applied Time-Series Analysis	Lecture 26 - Lecture 11 - Part 3 - Autocovariance & Autocorrelation Functions 1
Link	NOC:Applied Time-Series Analysis	Lecture 27 - Lecture 12 - Part 1 - Autocovariance & Autocorrelation Functions 2
Link	NOC:Applied Time-Series Analysis	Lecture 28 - Lecture 12 - Part 2 - Autocovariance & Autocorrelation Functions 3
Link	NOC:Applied Time-Series Analysis	Lecture 29 - Lecture 13 - Part 1 - Autocovariance & Autocorrelation Functions 4
Link	NOC:Applied Time-Series Analysis	Lecture 30 - Lecture 13 - Part 2 - Autocovariance & Autocorrelation Functions 5
Link	NOC:Applied Time-Series Analysis	Lecture 31 - Lecture 13 - Part 3 - Autocovariance & Autocorrelation Functions 6
Link	NOC:Applied Time-Series Analysis	Lecture 32 - Lecture 14 - Part 1 - Autocovariance & Autocorrelation Functions 7
Link	NOC:Applied Time-Series Analysis	Lecture 33 - Lecture 14 - Part 2 - Autocovariance & Autocorrelation Functions 8
Link	NOC:Applied Time-Series Analysis	Lecture 34 - Lecture 15 - Part 1 - Autocovariance & Autocorrelation Functions 9
Link	NOC:Applied Time-Series Analysis	Lecture 35 - Lecture 15 - Part 2 - Partial Autocorrelation Functions
Link	NOC:Applied Time-Series Analysis	Lecture 36 - Lecture 16 - Part 1 - Autocorrelation and Partial-autocorrelation Functions (with R Demonstration)
Link	NOC:Applied Time-Series Analysis	Lecture 37 - Lecture 16 - Part 2 - Models for Linear Stationary Processes 1
Link	NOC:Applied Time-Series Analysis	Lecture 38 - Lecture 17 - Part 1 - Models for Linear Stationary Processes 2
Link	NOC:Applied Time-Series Analysis	Lecture 39 - Lecture 17 - Part 2 - Models for Linear Stationary Processes 3
Link	NOC:Applied Time-Series Analysis	Lecture 40 - Lecture 18 - Part 1 - Models for Linear Stationary Processes 4
Link	NOC:Applied Time-Series Analysis	Lecture 41 - Lecture 18 - Part 2 - Models for Linear Stationary Processes 5
Link	NOC:Applied Time-Series Analysis	Lecture 42 - Lecture 18 - Part 3 - Models for Linear Stationary Processes 6
Link	NOC:Applied Time-Series Analysis	Lecture 43 - Lecture 19 - Part 1 - Models for Linear Stationary Processes 7
Link	NOC:Applied Time-Series Analysis	Lecture 44 - Lecture 19 - Part 2 - Models for Linear Stationary Processes 8
Link	NOC:Applied Time-Series Analysis	Lecture 45 - Lecture 19 - Part 3 - Models for Linear Stationary Processes 9
Link	NOC:Applied Time-Series Analysis	Lecture 46 - Lecture 20 - Part 1 - Models for Linear Stationary Processes 10
Link	NOC:Applied Time-Series Analysis	Lecture 47 - Lecture 20 - Part 2 - Models for Linear Stationary Processes 11
Link	NOC:Applied Time-Series Analysis	Lecture 48 - Lecture 21 - Part 1 - Models for Linear Stationary Processes 12
Link	NOC:Applied Time-Series Analysis	Lecture 49 - Lecture 21 - Part 2 - Models for Linear Stationary Processes 13
Link	NOC:Applied Time-Series Analysis	Lecture 50 - Lecture 22 - Part 1 - Models for Linear Stationary Processes 14 (with R Demonstrations)
Link	NOC:Applied Time-Series Analysis	Lecture 51 - Lecture 22 - Part 2 - Models for Linear Stationary Processes 15 (with R Demonstrations)
Link	NOC:Applied Time-Series Analysis	Lecture 52 - Lecture 22 - Part 3 - Models for Linear Stationary Processes 16 (with R Demonstrations)
Link	NOC:Applied Time-Series Analysis	Lecture 53 - Lecture 23 - Part 1 - Models for Linear Non-stationary Processes 1
Link	NOC:Applied Time-Series Analysis	Lecture 54 - Lecture 23 - Part 2 - Models for Linear Non-stationary Processes 2 (with R Demonstrations)
Link	NOC:Applied Time-Series Analysis	Lecture 55 - Lecture 24 - Part 1 - Models for Linear Non-stationary Processes 3 (with R Demonstrations)
Link	NOC:Applied Time-Series Analysis	Lecture 56 - Lecture 24 - Part 2 - Models for Linear Non-stationary Processes 4
Link	NOC:Applied Time-Series Analysis	Lecture 57 - Lecture 25 - Part 1 - Models for Linear Non-stationary Processes 5
Link	NOC:Applied Time-Series Analysis	Lecture 58 - Lecture 25 - Part 2 - Models for Linear Non-stationary Processes 6 (with R Demonstrations)
Link	NOC:Applied Time-Series Analysis	Lecture 59 - Lecture 26 - Part 1 - Fourier Transforms for Deterministic Signals 1
Link	NOC:Applied Time-Series Analysis	Lecture 60 - Lecture 26 - Part 2 - Fourier Transforms for Deterministic Signals 2
Link	NOC:Applied Time-Series Analysis	Lecture 61 - Lecture 27 - Part 1 - Fourier Transforms for Deterministic Signals 3
Link	NOC:Applied Time-Series Analysis	Lecture 62 - Lecture 27 - Part 2 - Fourier Transforms for Deterministic Signals 4
Link	NOC:Applied Time-Series Analysis	Lecture 63 - Lecture 28 - Part 1 - Fourier Transforms for Deterministic Signals 5
Link	NOC:Applied Time-Series Analysis	Lecture 64 - Lecture 28 - Part 2 - Fourier Transforms for Deterministic Signals 6
Link	NOC:Applied Time-Series Analysis	Lecture 65 - Lecture 29 - Part 1 - Fourier Transforms for Deterministic Signals 7
Link	NOC:Applied Time-Series Analysis	Lecture 66 - Lecture 29 - Part 2 - Fourier Transforms for Deterministic Signals 8
Link	NOC:Applied Time-Series Analysis	Lecture 67 - Lecture 30 - Part 1 - Fourier Transforms for Deterministic Signals 9
Link	NOC:Applied Time-Series Analysis	Lecture 68 - Lecture 30 - Part 2 - DFT and Periodogram 1
Link	NOC:Applied Time-Series Analysis	Lecture 69 - Lecture 31 - Part 1 - DFT and Periodogram 2
Link	NOC:Applied Time-Series Analysis	Lecture 70 - Lecture 31 - Part 2 - DFT and Periodogram 3 (with R Demonstrations)
Link	NOC:Applied Time-Series Analysis	Lecture 71 - Lecture 32 - Part 1 - Spectral Representations of Random Processes 1
Link	NOC:Applied Time-Series Analysis	Lecture 72 - Lecture 32 - Part 2 - Spectral Representations of Random Processes 2
Link	NOC:Applied Time-Series Analysis	Lecture 73 - Lecture 33 - Part 1 - Spectral Representations of Random Processes 3
Link	NOC:Applied Time-Series Analysis	Lecture 74 - Lecture 33 - Part 2 - Spectral Representations of Random Processes 4
Link	NOC:Applied Time-Series Analysis	Lecture 75 - Lecture 33 - Part 3 - Spectral Representations of Random Processes 5
Link	NOC:Applied Time-Series Analysis	Lecture 76 - Lecture 34 - Part 1 - Spectral Representations of Random Processes 6
Link	NOC:Applied Time-Series Analysis	Lecture 77 - Lecture 34 - Part 2 - Spectral Representations of Random Processes 7
Link	NOC:Applied Time-Series Analysis	Lecture 78 - Lecture 35 - Part 1 - Introduction to Estimation Theory 1
Link	NOC:Applied Time-Series Analysis	Lecture 79 - Lecture 35 - Part 2 - Introduction to Estimation Theory 2
Link	NOC:Applied Time-Series Analysis	Lecture 80 - Lecture 35 - Part 3 - Introduction to Estimation Theory 3
Link	NOC:Applied Time-Series Analysis	Lecture 81 - Lecture 36A - Introduction to Estimation Theory -4
Link	NOC:Applied Time-Series Analysis	Lecture 82 - Lecture 36B - Goodness of Estimators 1 - 1
Link	NOC:Applied Time-Series Analysis	Lecture 83 - Lecture 37A - Goodness of Estimators 1 - 2
Link	NOC:Applied Time-Series Analysis	Lecture 84 - Lecture 37B - Goodness of Estimators 1 - 3
Link	NOC:Applied Time-Series Analysis	Lecture 85 - Lecture 37C - Goodness of Estimators 1 - 4
Link	NOC:Applied Time-Series Analysis	Lecture 86 - Lecture 38A - Goodness of Estimators 2 - 1
Link	NOC:Applied Time-Series Analysis	Lecture 87 - Lecture 38B - Goodness of Estimators 2 - 2
Link	NOC:Applied Time-Series Analysis	Lecture 88 - Lecture 38C - Goodness of Estimators 2 - 3
Link	NOC:Applied Time-Series Analysis	Lecture 89 - Lecture 39A - Goodness of Estimators 2 - 4
Link	NOC:Applied Time-Series Analysis	Lecture 90 - Lecture 39B - Goodness of Estimators 2 - 5 (with R demonstrations)
Link	NOC:Applied Time-Series Analysis	Lecture 91 - Lecture 39C - Goodness of Estimators 2 - 6
Link	NOC:Applied Time-Series Analysis	Lecture 92 - Lecture 40A - Goodness of Estimators 2 - 7
Link	NOC:Applied Time-Series Analysis	Lecture 93 - Lecture 40B - Goodness of Estimators 2 - 8
Link	NOC:Applied Time-Series Analysis	Lecture 94 - Lecture 41A - Estimation Methods 1 - 1
Link	NOC:Applied Time-Series Analysis	Lecture 95 - Lecture 41B - Estimation Methods 1 - 2
Link	NOC:Applied Time-Series Analysis	Lecture 96 - Lecture 42A - Estimation Methods 1 - 3
Link	NOC:Applied Time-Series Analysis	Lecture 97 - Lecture 42B - Estimation Methods 1 - 4
Link	NOC:Applied Time-Series Analysis	Lecture 98 - Lecture 42C - Estimation Methods 1 - 5
Link	NOC:Applied Time-Series Analysis	Lecture 99 - Lecture 43A - Estimation Methods 1 - 6 (with R demonstrations)
Link	NOC:Applied Time-Series Analysis	Lecture 100 - Lecture 43B - Estimation Methods 1 - 7 (with R demonstrations)
Link	NOC:Applied Time-Series Analysis	Lecture 101 - Lecture 44A - Estimation Methods 1 - 8
Link	NOC:Applied Time-Series Analysis	Lecture 102 - Lecture 44B - Estimation Methods 1 - 9
Link	NOC:Applied Time-Series Analysis	Lecture 103 - Lecture 44C - Estimation Methods 2 - 1
Link	NOC:Applied Time-Series Analysis	Lecture 104 - Lecture 45A - Estimation Methods 2 - 2
Link	NOC:Applied Time-Series Analysis	Lecture 105 - Lecture 45B - Estimation Methods 2 - 3
Link	NOC:Applied Time-Series Analysis	Lecture 106 - Lecture 46A - MLE and Bayesian Estimation - 1
Link	NOC:Applied Time-Series Analysis	Lecture 107 - Lecture 46B - MLE and Bayesian Estimation - 2
Link	NOC:Applied Time-Series Analysis	Lecture 108 - Lecture 47A - MLE and Bayesian Estimation - 3
Link	NOC:Applied Time-Series Analysis	Lecture 109 - Lecture 47B - MLE and Bayesian Estimation - 4
Link	NOC:Applied Time-Series Analysis	Lecture 110 - Lecture 48A - Estimation of Time Domain Statistics - 1
Link	NOC:Applied Time-Series Analysis	Lecture 111 - Lecture 48B - Estimation of Time Domain Statistics - 2
Link	NOC:Applied Time-Series Analysis	Lecture 112 - Lecture 49 - Periodogram as PSD Estimator
Link	NOC:Rheology of Complex Materials	Lecture 1 - Flow phenomena in complex materials and Microstructure - 1
Link	NOC:Rheology of Complex Materials	Lecture 2 - Flow phenomena in complex materials and Microstructure - 2
Link	NOC:Rheology of Complex Materials	Lecture 3 - Applications of rheology : mechanisms at the molecular and microscopic scales - 1
Link	NOC:Rheology of Complex Materials	Lecture 4 - Applications of rheology : mechanisms at the molecular and microscopic scales - 2
Link	NOC:Rheology of Complex Materials	Lecture 5 - Applications of rheology : some example material systems - 1
Link	NOC:Rheology of Complex Materials	Lecture 6 - Applications of rheology : some example material systems - 2
Link	NOC:Rheology of Complex Materials	Lecture 7 - Stress and strain rate - 1
Link	NOC:Rheology of Complex Materials	Lecture 8 - Stress and strain rate - 2
Link	NOC:Rheology of Complex Materials	Lecture 9 - Velocity gradient and strain rate - 1
Link	NOC:Rheology of Complex Materials	Lecture 10 - Velocity gradient and strain rate 1 Stress and strain rate - 3
Link	NOC:Rheology of Complex Materials	Lecture 11 - Kinematics for simple flows - 1
Link	NOC:Rheology of Complex Materials	Lecture 12 - Kinematics for simple flows - 2
Link	NOC:Rheology of Complex Materials	Lecture 13 - Introduction to tensors
Link	NOC:Rheology of Complex Materials	Lecture 14 - Rheometric flows
Link	NOC:Rheology of Complex Materials	Lecture 15 - Viscous response - 1
Link	NOC:Rheology of Complex Materials	Lecture 16 - Viscous response - 2
Link	NOC:Rheology of Complex Materials	Lecture 17 - Viscoelasticity - Relaxation process
Link	NOC:Rheology of Complex Materials	Lecture 18 - Viscoelasticity - Maxwell model
Link	NOC:Rheology of Complex Materials	Lecture 19 - Linear viscoelasticity - oscillatory shear - 1
Link	NOC:Rheology of Complex Materials	Lecture 20 - Linear viscoelasticity - oscillatory shear - 2
Link	NOC:Rheology of Complex Materials	Lecture 21 - Introduction to tensors - 2
Link	NOC:Rheology of Complex Materials	Lecture 22 - Introduction to tensors - 3
Link	NOC:Rheology of Complex Materials	Lecture 23 - Rheometers - 1
Link	NOC:Rheology of Complex Materials	Lecture 24 - Rheometers - 2
Link	NOC:Rheology of Complex Materials	Lecture 25 - Rheometers - 3
Link	NOC:Rheology of Complex Materials	Lecture 26 - Rheometers - 4
Link	NOC:Rheology of Complex Materials	Lecture 27 - Rheometers - 5
Link	NOC:Rheology of Complex Materials	Lecture 28 - Governing equations for rheology - 1
Link	NOC:Rheology of Complex Materials	Lecture 29 - Governing equations for rheology - 2
Link	NOC:Rheology of Complex Materials	Lecture 30 - Relaxation time spectrum - 1
Link	NOC:Rheology of Complex Materials	Lecture 31 - Relaxation time spectrum - 2
Link	NOC:Rheology of Complex Materials	Lecture 32 - Linear viscoelasticity: generalized Maxwell model
Link	NOC:Rheology of Complex Materials	Lecture 33 - Time temperature superposition
Link	NOC:Rheology of Complex Materials	Lecture 34 - Linear viscoelasticity: solidlike materials
Link	NOC:Rheology of Complex Materials	Lecture 35 - General linear viscoelasticity
Link	NOC:Rheology of Complex Materials	Lecture 36 - Rotational rheometry
Link	NOC:Rheology of Complex Materials	Lecture 37 - Review of material functions - 1
Link	NOC:Rheology of Complex Materials	Lecture 38 - Review of material functions - 2
Link	NOC:Rheology of Complex Materials	Lecture 39 - Survey of material functions for polymers - 1
Link	NOC:Rheology of Complex Materials	Lecture 40 - Survey of material functions for polymers - 2
Link	NOC:Rheology of Complex Materials	Lecture 41 - Survey of material functions for polymers - 3
Link	NOC:Rheology of Complex Materials	Lecture 42 - Survey of material functions for polymers - 4