subjectId	Discipline Name	Subject Name	Coordinators	Type	Institute	Content
103101001	Chemical Engineering	Advanced Chemical Reaction Engineering (PG)	Prof. H.S. Shankar	Video	IIT Bombay	Select L1-Course Overview � I L2-Course Overview � II L3-Design Equations � I L4-Design Equations � Illustrative Examples L5-Design Equations II : Plug Flow Recycle Reactors L6-Illustrative Examples :1) Plug Flow Recycle 2) Multiple reactions � I L7-Illustrative Examples :1) Recycle Reactor with Condenser 2) CSTR with Recycle L8-Multiple Reactions � II L9-Modelling Multiple Reactions in Soil Environment � III L10-Semi Continuous Reactor Operation L11-Catalyst Deactivation � I L12-Catalyst Deactivation � II L13-Illustrative Example : 1) Determination of deactivation Parameters 2) Design for Deactivating Catalyst L14-Energy Balance � I L15-Energy Balance � II L16-Reacting Fluids as Energy Carrier L17-Illustrative Example : Energy Balance in Stirred Vessels L18-Energy Balance � III : Design for Constant T Operation L19-Energy Balance � IV : Temperature Effects on Rate & Equilibria L20-Energy Balance � V : Stability Analysis of Exothermic Stirred Tank L21-Illustrative Example : Stability of Exothermic Stirred Tank L22-Energy Balance � VI : 1) Tubular Reactor Heated/Cooled from Wall 2) Transient Behavior of CSTR L23-Illustrative Example : 1) Plug Flow with Heat Effects 2) Multiple Reactions L24-Illustrative Example : 1) Further Considerations in Energy Balance 2) Multiple Reactions L25-Illustrative Example : 1) Hot Spot as Design Basis 2) Design for Instantaneous Reactions L26-Residence Time Distribution Methods L27-Residence Time Distribution Models L28-Shrinking core Gas-Solid reactions Model L29-Shrinking core Ash Diffusion Model & Combination of Resistances L30-1) Gas Solid Reactions Temperature Effects on Rate & Equilibria 2) Introduction to Population Balance �I L31-Illustrative Example : Temperature Effects on Rate & Equilibria L32-Population Balance Modelling � II L33-Population Balance Modelling � III L34-Illustrative Examples : Population Balance Models L35-Introduction to Environmental Reactions L36-Reaction Engineering Examples in Biochemical & Environmental Engineering L37-Illustrative Examples : 1) Biomethanation 2) Alcohol via Fermentation 3) Natural Selection L38-Illustrative Examples : 1) Enzyme Reaction 2) Microbial Reaction 3) Waste Treatment L39-Oxygen Sag Analysis in Rivers L40-Illustrative Examples : 1) Oxygen Sag Analysis 2) Population Balance Modelling of Forest 3) Sponge Iron Process L41-Illustrative Example : Gas- Solid Reaction RTD Models Reaction Network
103101003	Chemical Engineering	Advanced Process Control	Prof. Sachin C. Patwardhan	Video	IIT Bombay	Select Lecture 1-Introduction and Motivation Lecture 2-Linearization of Mechanistic Models Lecture 3-Linearization of Mechanistic Models (Contd.) Lecture 4-Introduction to z-transforms and Development of Grey-box models Lecture 5-Introduction to Stability Analysis and Development of Output Error Models Lecture 6-Introduction to Stochastic Processes Lecture 7-Introduction to Stochastic Processes (Contd.) Lecture 8-Development of ARX models Lecture 9-Statistical Properties of ARX models and Development of ARMAX models Lecture 10-Development of ARMAX models (contd.) and Issues in Model Development Lecture 11-Model Structure Selection and Issues in Model Development (contd.) Lecture 12-Issues in Model Development (contd.) and State Realizations of Transfer Function Models Lecture 13-Stability Analysis of Discrete Time Systems Lecture 14-Lyapunov Functions and Interaction Analysis and Multi-loop Control Lecture 15-Interaction Analysis and Multi-loop Control (contd.) Lecture 16-Multivariable Decoupling Control and Soft Sensing and State Estimation Lecture 17-Development of Luenberger Observer Lecture 18-Development of Luenberger Observer (contd.) and Introduction to Kalman Filtering Lecture 19-Kalman Filtering Lecture 20-Kalman Filtering (contd.) Lecture 21-Kalman Filtering (contd.) Lecture 22-Pole Placement State Feedback Control Design and Introduction to Linear Quadratic Gaussian (LQG) Control Lecture 23-Linear Quadratic Gaussian (LQG) Regulator Design Lecture 24-Linear Quadratic Gaussian (LQG) Controller Design Lecture 25-Model Predictive Control (MPC) Lecture 26-Model Predictive Control (contd.)
103101004	Chemical Engineering	Chemical Engineering Thermodynamics	Dr. Sandip Roy	Web	IIT Bombay	Select Section 1 : Introduction Section 2 : Thermodynamic System: Select Definitions Section 3 : Types of Energies associated with Thermodynamic Processes Section 4 : Thermodynamic Equilibrium Section 5 : The Phase Rule Section 6 : Zeroth Law of Thermodynamics and Absolute Temperature Section 7 : The Ideal Gas Section 8 : State and Path Dependent Thermodynamic Variables Section 9 : Reversible and Irreversible Thermodynamic Processes Section 10 :Significance of Chemical Engineering Thermodynamics: Process Plant Schema Section 1 : General P-V-T Behaviour of Real Fluids Section 2 : Origins of Deviation from Ideal Gas Behaviour Section 3 : Equations of State for Real Fluids Section 4 : Volumetric Properties of Mixtures Section 5 : Property Representation of 2-phase systems Section 6 : Heat Effects of Phase Change Section 1 : Concept of Internal Energy Section 2 : The First Law of Thermodynamics Section 3 : Application of the First Law to Open Systems Section 4 : Measurement of Enthalpy and Internal Energy using Flow Calorimeter Section 1 : Heat Engins and Second Law Statements Section 2 : Carnot Heat Engine Cycle and the 2nd Law Section 3 : Entropy Calculations for Ideal Gases Section 4 : Mathematical Statement of the 2nd Law Section 5 : Entropy Balance for Open Systems Section 6 : Ideal and Lost Work for Flow Systems Section 7: Appendix 4.1 Section 1 : Thermodynamic Property Relations for Single Phase Systems Section 2 : Maxwell Relations Section 3 : Relations for Enthalpy, Entropy and Internal Energy Section 4 : Residual Property Relations Section 5 : Residual Property Calculation from EOS Section 6 : Generalized Correlations for computing dH and dS for a real gas Section 7 : Computation of ?H and ?S for a Gas using Generalized Departure Functions Section 8 : Extension to Gas Mixtures Section 9 : Relations for ?H and ?S for Liquids Section 10 : Applications to real fluid processes in process plant equipments Section 1 : Partial Molar Property Section 2 : Partial Properties for Binary Solutions Section 3 : Criteria of Thermodynamic Equilibrium Section 4 : The Chemical Potential Section 5 : Ideal Gas Mixtures and Liquid Solutions Section 6 : Excess Properties Section 7 : Fugacity of pure substances Section 8 : Fugacity-based phase equilibrium criterion for pure component system Section 9 : Fugacity expressions for pure gases Section 10 : Generalized Correlations for the Fugacity Coefficient Section 11 : Expression for Fugacity of a Pure Liquid Section 12 : Fugacity and Fugacity Coefficient of Species in Mixture Section 13 :Relation between residual property and species fugacity coefficients in mixtures Section 14 : Expressions for gas phase using EOS Section 15 : The Lewis/Randall Rule Section 16 : Dependence of Excess Gibbs free energy on temperature and pressure Section 17 : The Activity Coefficient Section 18 : Use of VLE data for generation of Activity Coefficient Models Section 19 : Activity Coefficient Models Section 20 : Appendix 6.1 Section 21 : Appendix 6.2 Section 1 :Introduction of Vapour-Liquid equilibria Section 2 : Single Component System Phase Equilibria Section 3 : Derivation of the Phase Rule Section 4 : Description of General VLE Behavior Section 5 : Raoult�s Law for VLE Section 6 : VLE Algorithms for Low to Moderate Pressures Section 7 : High Pressure Vapour Liquid Equilibria Section 8 : Henry�s Law Section 1 : Introduction of Chemical Reaction Equilibria Section 2 : Standard Enthalpy and Gibbs free energy of reaction Section 3 : The Reaction Coordinate Section 4 : Criteria for Chemical Reaction Equilibrium Section 5 : The Equilibrium Constant of Reaction Section 6 : Reactions involving gaseous species Section 7 : Reaction equilibria for simultaneous reactions Section 8 : Reactions involving Liquids and Solids Section 1 : Liquid-liquid Equilibria (LLE) Section 2 : Solid-Liquid Equilibria Section 3 : Solid-Vapour Equilibrium
103101008	Chemical Engineering	Chemical Reaction Engineering II	Prof. A.K. Suresh, Prof. Sanjay M. Mahajani, Prof. Ganesh A. Viswanathan	Video	IIT Bombay	Select L1-Introduction to catalysts and catalysis L2-Steps in catalytic reaction: adsorption, desorption and reaction L3-Derivation of the rate equation L4-Heterogenous data analysis for reactor design - I L5-Heterogenous data analysis for reactor design - II L6-Catalyst deactivation and accounting for it in design � I L7-Catalyst deactivation and accounting for it in design � II L8-Synthesize the rate equation L9-Introduction to intraparticle diffusion L10-Intraparticle diffusion: Thiele modulus and effectiveness factor Part I L11-Intraparticle diffusion: Thiele modulus and effectiveness factor Part II L12-Intraparticle diffusion: Thiele modulus and effectiveness factor Part III L13-Effectiveness factor and Introduction to external mass transfer L14-External Mass Transfer L15-Implications to rate data interpretation and design I L16-Implications to rate data interpretation and design II L17-Packed-bed reactor design L18-Fluidized bed reactor design I L19-Fluidized bed reactor design II L20-Gas-liquid reactions-1: Theories of mass transfer into agitated liquids L21-GLR-2: Effect of chemical reaction on mass transfer: the slow reaction regime L22-GLR-3: Transition to fast reaction, and the Fast reaction regime L23-GLR-4: Fast reaction example; Instantaneous reaction regime L24-GLR-5: Transition to Instantaneous reaction; Reaction regimes in surface renewal theories L25-GLR-6: Reaction regimes in surface renewal theories (contd..) L26-GLR-7: Surface renewal theories: Instantaneous reaction and Summing up L27-Fluid-solid non-catalytic reactions I L28-Fluid-solid non-catalytic reactions II L29-Fluid-solid non-catalytic reactions III L30-Distribution of residence time L31-Measurement of residence time distribution L32-Residence time distribution function L33-Reactor diagnostics and troubleshooting L34-Modeling non-ideal reactors L35-Residence time distribution: Performance of non-ideal reactors L36-Non-ideal Reactors: Tanks-in-series model L37-Non-ideal Reactors: Dispersion model L38-Non-ideal Reactors: Dispersion model and introduction to multiparameter models L39-Non-ideal Reactors: Multiparameter models
103101009	Chemical Engineering	Advanced Numerical Analysis	Prof. Sachin C. Patwardhan	Web	IIT Bombay	Select Overview of the Course Section 1 : Introductions Section 2 : Lumped Parameter Models and Abstract Equation Formss Section 3 : Distributed Parameter Models and Abstract Equation Formss Section -1 : Introduction Section 2 : VectorSpaces Section 3 : Normed Linear Spaces and Banach Spaces Section 4 : Inner Product Spaces and Hilbert Spaces Section 5 : Gram-Schmidt Process and Orthogonal Polynomials Section 6 : Induced Matrix Norms Section 7 : Summary Section 1 : Unified Problem Representation Section 2 : Polynomial Approximation[3] Section 3 : Discretization using Taylor Series Approximation Section 4 : Discretization using Polynomial Interpolation Section 5 : Least Square Approximations Section 6 : Errors in Discretization and Computations[4] Section 7 : Summary and Conclusions Section 8 : Appendix: Necessary and Sufficient Conditions for Unconstrained Optimality Section 1-Introduction Section 2 : Existence of Solutions Section 3 : Direct Solution Techniques Section 4 : Direct Methods for Solving Sparse Linear Systems Section 5 : Iterative Solution Techniques Section 6 : Optimization Based Methods Section 7 : Matrix Conditioning and Behavior of Solutions Section 8 : Summary Section 9 : Appendix A: Behavior of Solutions of Linear Difference Equations Section 10 : Appendix B: Theorems on Convergence of Iterative Schemes Section 11 : Appendix C: Steepest Descent / Gradient Search Method Section 1: Introduction Section 2 : Method of Successive Substitutions [4] Section 3 : Newton�s Method Section 4 : Solutions of Nonlinear Algebraic Equations Using Optimization Section 5 : Condition Number of Nonlinear Set of Equations [7] Section 6 : Existence of Solutions and Convergence of Iterative Methods [12] Section 7 :Summary Section 1 :Introduction Section 2 : Existence, Uniqueness and Continuity of Solutions [1] Section 3 : Analytical Solutions of Linear ODE-IVPs Section 4 : Numerical Solution Schemes: Basic Concepts Section 5 : Numerical Methods Based On Taylor Series Expansion[2] Section 6 : Numerical Methods Based on Polynomial Interpolation [2] Section 7 : Convergence Analysis and Selection of Integration Interval Section 8 : Solutions of Differential Algebraic System of Equations Section 9 :Solution of ODE-BVP using Shooting Method [3] Section 10 : Summary Section 11 : Exercise Section 12: Excercise Section 8: Excercise Section 4 : Summary
103101111	Chemical Engineering	Advanced Numerical Analysis	Prof. Sachin C. Patwardhan	Video	IIT Bombay	Select Lecture 1: Introduction and Overview Lecture -2 Fundamentals of Vector Spaces Lecture 3 : Basic Dimension and Sub-space of a Vector Space Lecture 4 : Introduction to Normed Vector Spaces Lecture 5 : Examples of Norms,Cauchy Sequence and Convergence, Introduction to Banach Spaces Lecture 6 : Introduction to Inner Product Spaces Lecture 7 : Cauchy Schwaz Inequality and Orthogonal Sets Lecture 8 : Gram-Schmidt Process and Generation of Orthogonal Sets Lecture 9 : Problem Discretization Using Appropriation Theory Lecture 10 : Weierstrass Theorem and Polynomial Approximation Lecture 11 : Taylor Series Approximation and Newton's Method Lecture 12 : Solving ODE - BVPs Using Firute Difference Method Lecture 13 :Solving ODE - BVPs and PDEs Using Finite Difference Method Lecture 14 : Finite Difference Method (contd.) and Polynomial Interpolations Lecture 15 : Polynomial and Function Interpolations,Orthogonal Collocations Method for Solving ODE -BVPs Lecture 16 : Orthogonal Collocations Method for Solving ODE - BVPs and PDEs Lecture 17 :Least Square Approximations, Necessary and Sufficient Conditions for Unconstrained Optimization Lecture 18 : Least Square Approximations :Necessary and Sufficient Conditions for Unconstrained Optimization Least Square Approximations ( contd..) Lecture 19 :Linear Least Square Estimation and Geometric Interpretation of the Least Square Solution Lecture 20 : Geometric Interpretation of the Least Square Solution (Contd.) and Projection Theorem in a Hilbert Spaces Lecture 21 : Projection Theorem in a Hilbert Spaces (Contd.) and Approximation Using Orthogonal Basis Lecture 22 :Discretization of ODE-BVP using Least Square Approximation Lecture 23 : Discretization of ODE-BVP using Least Square Approximation and Gelarkin Method Lecture 24 : Model Parameter Estimation using Gauss-Newton Method Lecture 25 : Solving Linear Algebraic Equations and Methods of Sparse Linear Systems Lecture 26 : Methods of Sparse Linear Systems (Contd.) and Iterative Methods for Solving Linear Algebraic Equations Lecture 27 : Iterative Methods for Solving Linear Algebraic Equations Lecture 28 : Iterative Methods for Solving Linear Algebraic Equations: Convergence Analysis using Eigenvalues Lecture 29 :Iterative Methods for Solving Linear Algebraic Equations: Convergence Analysis using Matrix Norms Lecture 30 : Iterative Methods for Solving Linear Algebraic Equations: Convergence Analysis using Matrix Norms (Contd.) Lecture 31 : Iterative Methods for Solving Linear Algebraic Equations: Convergence Analysis (Contd.) Lecture 32 :Optimization Based Methods for Solving Linear Algebraic Equations: Gradient Method Lecture 33 : Conjugate Gradient Method, Matrix Conditioning and Solutions of Linear Algebraic Equations Lecture 34 : Matrix Conditioning and Solutions and Linear Algebraic Equations (Contd.) Lecture 35 : Matrix Conditioning (Contd.) and Solving Nonlinear Algebraic Equations Lecture 36 : Solving Nonlinear Algebraic Equations: Wegstein Method and Variants of Newton's Method Lecture 37 : Solving Nonlinear Algebraic Equations: Optimization Based Methods Lecture 38 : Solving Nonlinear Algebraic Equations: Introduction to Convergence analysis of Iterative Solution Techniques Lecture 39 : Solving Nonlinear Algebraic Equations: Introduction to Convergence analysis (Contd.) and Solving ODE-IVPs Lecture 40 :Solving Ordinary Differential Equations - Initial Value Problems (ODE-IVPs) : Basic Concepts Lecture 41 :Solving Ordinary Differential Equations - Initial Value Problems (ODE-IVPs) : Runge Kutta Methods Lecture 42 :Solving ODE-IVPs : Runge Kutta Methods (contd.) and Multi-step Methods Lecture 43 :Solving ODE-IVPs : Generalized Formulation of Multi-step Methods Lecture 44 : Solving ODE-IVPs : Multi-step Methods (contd.) and Orthogonal Collocations Method Lecture 45 : Solving ODE-IVPs: Selection of Integration Interval and Convergence Analysis of Solution Schemes Lecture 46 : Solving ODE-IVPs: Convergence Analysis of Solution Schemes (contd.) Lecture 47 :Solving ODE-IVPs: Convergence Analysis of Solution Schemes (contd.) and Solving ODE-BVP using Single Shooting Method Lecture 48 : Methods for Solving System of Differential Algebraic Equations Lecture 49 : Methods for Solving System of Differential Algebraic Equations (contd.) and Concluding Remarks
103102012	Chemical Engineering	Heterogeneous Catalysis and Catalytic Processes	Dr. K.K. Pant	Video	IIT Delhi	Select mod01lec01.mp4 mod01lec02.mp4 mod01lec03.mp4 mod02lec04.mp4 mod02lec05.mp4 mod02lec06.mp4 mod03lec07.mp4 mod03lec08.mp4 mod03lec09.mp4 mod03lec10.mp4 mod04lec11.mp4 mod04lec12.mp4 mod04lec13.mp4 mod04lec14.mp4 mod05lec15.mp4 mod05lec16.mp4 mod06lec17.mp4 mod06lec18.mp4 mod07lec19.mp4 mod07lec20.mp4 mod07lec21.mp4 mod08lec22.mp4 mod08lec23.mp4 mod08lec24.mp4 mod09lec25.mp4 mod09lec26.mp4 mod09lec27.mp4 mod09lec28.mp4 mod09lec29.mp4 mod09lec30.mp4 mod09lec31.mp4 mod10lec32.mp4 mod10lec33.mp4 mod11lec34.mp4 mod11lec35.mp4 mod11lec36.mp4 mod11lec37.mp4 mod11lec38.mp4 mod11lec39.mp4 mod12lec40.mp4
103102015	Chemical Engineering	Fuel Cell Technology	Dr. Anil Verma, Prof. S. Basu	Web	IIT Delhi	Select Why we need fuel cell? Overview - History;Principle of fuel cell technology Basic electrochemistry for all the fuel cell Gibb�s free energy; reversible and irreversible losses; Fuel cell efficiency Nernst equation; Effect of temperature, pressure, concentration on Nernst potential Concept of electrochemical potential Activation polarization Concentration polarization Ohmic polarization Modelling of fuel cell: current-voltage predictions Electrolytes Catalysts Current collector/ bipolar plate Why characterization needed? Possible ways of characterization In-situ characterization especially I-V characteristics and electrochemical impedance spectroscopy; Cyclic voltammetry; Current interruption technique Ex-situ characterization especially electrolyte and bipolar plate SOFC - High Temperature Fuel Cell Comparison of low and high temperature fuel cells Hydrogen production Hydrogen Storage
103102022	Chemical Engineering	Petroleum Refinery Engineering	Dr. K.K. Pant ,Prof. Deepak Kunzru	Web	IIT Delhi	Select General Definition Introduction to petroleum refinery Classification of Crude oil Characterization of crude oil ,Composition of crude Physical properties Crude oil; analysis and distillation Introduction to refinery feed stocks and refinery products Dehydration and desalting of crude Crude Assay, ASTM, TBP distillations, evaluation of crude oil properties API gravity, Various average boiling points and mid percent corves Evaluation of properties of crude oil and its fractions Design concept of crude oil distillation column design Furnace design-1 Furnace design-2 Coking and Thermal process, Delayed coking Catalytic cracking, Cracking reactions, Zeolite catalysts Cracking Feedstocks and reactors, Effect of process variables FCC Cracking, Catalyst coking and regeneration, Design concepts, New Designs for Fluidized-Bed Catalytic Cracking Units Objective and application of catalytic reforming process, reforming catalyst Reformer feed, Reforming reactor design, Continuous and semi regenerative process Objectives & Hydrocracking Reactions,Hydrocracking feedstocks,Modes of Hydrocracking,Effects of process variables Hydro treating process and catalysts Resid hydro processing,Effects of process variables,Reactor design concepts Isomerization process, Reactions, Effects of process variables Alkylation process, Feedstocks, reactions, products, catalysts and effect of process variables Polymerization: Objectives, process, Reactions,catalysts and effect of process variables Lube oil processing:propane deasphalting Solvent extraction, dewaxing,Additives production from refinery feedstocks Ecological consideration in petroleum refinery,Waste water treatment,control of air pollution,New trends in refinery, Alternative energy sources, Biodiesel,Hydrogen energy from biomass
103102024	Chemical Engineering	Transport Phenomena (UG)	Prof. S.K. Gupta	Web	IIT Delhi	Select Vector and tensor analysis part 1"""""" Vector and tensor analysis part 2"""""" Vector and tensor analysis part 3"""""" Vector and tensor analysis part 4"""""" Vector and tensor analysis part 5"""""" Coordinate systems and time derivative""""" Introduction to momentum transport"""""" Introduction to momentum transport, Axiom 1 mass is conversed"" Axiom 2 momentum is conversed"""""" Solution of momentum transport problems by shell momentum balance part1 Solution of momentum transport problems by shell momentum balance part2 Solution of momentum transport problems by shell momentum balance part3 Solution of momentum transport problems by shell momentum balance part4 Solution of momentum transport problems by shell momentum balance part5 Derivation of equation of motion part 1""""" Derivation of equation of motion part 2""""" Solution of momentum transport problem by using Navier stokes equation part2 Introduction to Non-Newtonian fluids""""" Momentum transport problem for power law and Bingham fluid"" Tube Flow Problem For Bingham Fluid"""""" Coutte flow for Non-Newtonian fluid"""""" Appendix 1to3""""""""" Solution of heat transport problems by shell energy balance part1" Solution of heat transport problems by shell energy balance part2" Solution of heat transport problems by shell energy balance part3" Derivation of equation of energy part1""""" Derivation of equation of energy part2""""" Derivation of equation of energy part3""""" Derivation of equation of energy part4""""" solution of heat transport problems by equation of thermal energy part1 Solution of heat transport problems by equation of thermal energy part2 Appendix 4,5&6""""""""" Introduction to mass transport part 1""""" Introduction to mass transport part 2""""" Mass transport in binary systems special cases"""" Appendix 7&8"""""""""
103103026	Chemical Engineering	Catalyst Science and Technology	Dr. Mahuya De	Web	IIT Guwahati	Select Adsorption in Solid Catalysis Multilayer adsorption & Pore condensation Catalyst types and preparation Solgel Method Drying, Calcination & Formulation Introduction & Surface area analysis Pore Analysis XRD Analysis Chemisorption studies Thermal Analysis Spectroscopic analysis;FT-IR Spectroscopic analysis; Raman Electron Microscopy Catalyst Test and Reactor Types Reaction mechanism and rate equations Kinetic Analysis :Part 1 Kinetic Analysis :Part 2 External Transport : Part 1 External Transport Part 2 + Internal Transport Part 1 Internal Transport : Part 2 Catalyst Deactivations Steam Reforming Part 1 Steam Reforming Part 2 +Petroleum Refining Part1 Petroleum Refining Part 2 Environment Catalysis Hydrogenation & Oxidation Catalysis Introduction & different types of reaction Mechanism and Kinetics :Part 1 Mechanism and Kinetics :Part 2 Industrial Homogeneous Process Enzyme catalysis Questions: Module 2 Zeolites Catalysts Polymerization Catalyst �Part 1 Polymerization Catalyst �Part 2 Carbon Nanotubes Nano Metal or Metal Oxide Catalysts Phase Transfer Catalysts Molecular Modeling: Introduction
103103027	Chemical Engineering	Chemical Engineering Design - II	Prof. Vaibhav V. Goud,Dr. Animes Kr. Golder	Web	IIT Guwahati	Select Heat Exchangers Classifications Thermal Design Considerations Process (Thermal) Design Procedure Design Problem Shell and Tube Exchanger for Two Phase Heat Transfer Condenser and Reboiler Design Mechanical Design Standards Design Components � I Design Components � II Hand on Calculations Introduction and Evaporator Classifications Methods of Feeding of Evaporators Thermal Design Calculation Solved Example Mechanical Design I Introduction and Types of Driers Introduction and types of Driers (Cont.) Design Consideration of Driers Solved Problems Mechanical Design II Separation Equipments I General Design Considerations Exercise Problems Centrifuges Centrifuges(Cont.) Separation EquipmentsII Exercise Problems II Introduction, Axial Stress Due to Dead Loads Axial Stresses Due to Pressures Longitudinal Bending Stresses Due to Dynamic Loads, Design Considerations Solved Problem1 Solved Problem 2 Introduction Effect Vapor Flow Conditions on Tray Design Plate Design Hand on Design Provisional Plate Design1 Provisional Plate Design2 Column Construction and Internals Stresses Developed in Column Introduction and Process Hazards Safety Measures Safety measures in equipment design and Pressure Relief Devices
103103029	Chemical Engineering	Chemical Technology - II	Dr. U. Ramagopal	Web	IIT Guwahati	Select Orientation Orientation (cont�) Overview Overview of Refinery Processes Crude distillation Cracking Reforming and Isomerization Hydroprocessing Alkylation Visbreaking and Coking Gas Processing and Polymerization Refinery Supporting Processes Petrochemicals: Overview Formaldehyde and Chloromethanes Hydrocarbon Steam Cracking for Petrochemicals Vinyl Chloride from Ethylene Ethylene oxide and Ethanolamines Isopropanol and Acetone from Propylene Cumene and Acrylonitrile from Propylene Isoprene and Oxoprocessing Butadiene and Benzene Manufacture Phenol from Cumene and Toluene Phenol from Benzene Styrene and Pthalic Anhydride Production Manufacture of Maleic Anhydride and DDT Industries Chemical recovery from black liquor Manufacture of sugar from sugarcane Manufacture of Ethanol from Molasses Soaps and Detergents Edible and Essential Oils Coke production Hydrogenation of Coal Introduction to Food Technology Food Processing Equipments Definitions and Nomenclature Classification According To Preparation Methods Processing Technologies Polymer Manufacturing Processes Manufacture of Phenol Formaldehyde, Viscose Rayon and Nylon
103103031	Chemical Engineering	Heat Transfer	Prof. A.K. Ghoshal	Video	IIT Guwahati	Select Introduction to heat transfer General heat conduction equation One dimensional steady state conduction in rectangular coordinate One dimensional steady state conduction in cylindrical and spherical coordinate Critical and optimum insulation Extended surface heat transfer 1 Extended surface heat transfer 2 Analysis of lumped parameter model Transient heat flow in semi infinite solid Infinite body subjected to sudden convective Graphical solutions of unsteady state heat conduction problem Dimensional analysis for forced convection Dimensional analysis for free convection Heat transfer co-relations for laminar and internal flows Heat transfer co-relations for turbulent and internal flows Co-relation for turbulent and external flows Heat transfer co-relations for flow across tube banks Momentum and heat transfer analogies Boundary layer heat transfer Boundary layer equations Approximate analysis in boundary layer Theoretical concepts of natural / free convention heat transfer Emperical relations for free convention heat transfer Condensation heat transfer over vertical plate Condensation heat transfer for various conditions & geometries Fundamentals of boiling heat transfer Boiling heat transfer co-relations Classification of heat exchangers Various types of shell and tube heat exchangers Various types of compact heat exchangers Effectiveness-NTU, method of heat exchanger analysis Design of double pipe heat exchanger Design of shell and tube heat exchanger Introduction to evaporation and evaporators Evaporation principles and evaporator performance Evaporator calculations Introduction to radiation heat transfer Radiation intensity and radiation view factor Radiation heat exchange Radiation shield and gas radiation
103103032	Chemical Engineering	Heat Transfer	Dr. Anil Verma	Web	IIT Guwahati	Select Lecture 1 Lecture 2 Lecture 3 Lecture 4 Lecture 5 Lecture 6 Lecture 7 Lecture 8 Lecture 9 Lecture 10 Lecture 11 Lecture 12 Lecture 13 Lecture 14 Lecture 15 Lecture 16 Lecture 17 Lecture 18 Lecture 19 Lecture 20 Lecture 21 Lecture 22 Lecture 23 Lecture 24 Lecture 25 Lecture 26 Lecture 27 Lecture 28 Lecture 29 Lecture 30 Lecture 31 Lecture 32 Lecture 33 Lecture 34 Lecture 35 Lecture 36 Lecture 37 Lecture 38 Lecture 39 Lecture 40 Problems: Module1 Problems: Module2 Problems: Module3 Problems: Module4 Problems: Module5 Problems: Module6 Problems: Module7 Problems: Module8 Problems: Module9
103103033	Chemical Engineering	Interfacial Engineering	Dr. Pallab Ghosh	Web	IIT Guwahati	Select Introduction to interfacial engineering Colloidal materials: part I Colloidal materials: part II Colloidal materials: part III Colloidal materials: part IV Colloidal materials: part V Surface tension Interfacial tension Shape of the interfaces Characterization of solid surfaces Deposition of thin films on solid surfaces Van der waals forces: part I Van der waals forces (part II) & electrostatic double layer force (part I) Electrostatic double layer force: part II Electrostatic double layer force: part III DLVO theory and non-DLVO forces Adsorption at fluid�fluid interfaces: part I Adsorption at fluid�fluid interfaces: part II Adsorption at fluid�fluid interfaces: part III Adsorption at fluid�solid interfaces Rheology of fluid�fluid interfaces: part I Rheology of fluid�fluid interfaces: part II Motion of drop in liquid, surface diffusion & thin liquid films (part I) Thin liquid films (part II) Emulsions, microemulsions and foams (part I) Emulsions, microemulsions and foams (part II) Emulsions, microemulsions and foams (part III) Emulsions, microemulsions and foams (part IV) Emulsions, microemulsions and foams (part V) Interfacial reactions (part I) Interfacial reactions (part II) Interfacial reactions (part III) Micellar and phase transfer catalyses Biointerfaces & adsorption of proteins at soild surfaces Adsorption of proteins at fluid�fluid interfaces Biological membranes and adhesion Interfacial forces & biomineralization Introduction to nanomaterials & nanotechnology Preparation of nanomaterials Nanotubes Froth flotation Microporous and mesoporous materials & lithographic techniques
103103034	Chemical Engineering	Mass Transfer Operations I	Dr. B. Mandal	Video	IIT Guwahati	Select Introduction to Mass Transfer Molecular Diffusion Fick�s Law of Diffusion Steady state molecular diffusion in fluids Part I Steady state molecular diffusion in fluids Part II Diffusion coefficient: Measurement and Prediction Part I Diffusion Coefficient: Measurement and Prediction Part II Multicomponent Diffusion and Diffusivity in Solids Concept of Mass Transfer Coefficient Dimensionless Groups and Co-relations for Convective Mass Transfer co-efficient in Laminar Flow Condition Boundary Layer Theory and Film Theory in Mass Transfer Mass Transfer Coefficients in Terbulant Flow Interphase Mass Transfer and Mass Transfer Theories Part I Interphase Mass Transfer and Mass Transfer Theories Part II Interphase Mass Transfer and Mass Transfer Theories Part 3 Agitated and Sparged Vassels Tray Column Part I Tray Column Part II Packed Tower Introduction to Absorption and Solvent selection Packed Tower Design Part I Packed Tower Design Part II Packed Tower Design Part III Mass Transfer Coefficients Correlation and HETP Concept Tray Tower Design and Introduction to Multicomponent System Introduction to Distillation and Phas diagrams Azeotropes and Enthalpy Concentration Diagrams Flash Distillation Batch and Steam Distillation Fractional Distillation Fractional Distillation: McCabe Thiele Method Fractional Distillation: Minimum Reflux and Pinch Point Fractional Distillation: Subcooled Reflux ,Tray Efficiency and Use of Open Steam Fractional Distillation: Multiple Feeds and Side Stream Multistage Batch Distillation with Reflux Fractional Distillation: Ponchan and Savarit Method Ponchan and Savarit Method and Packed Tower Distillation Multicomponent Distillation
103103035	Chemical Engineering	Mass Transfer Operations I	Dr. Chandan Das,Dr. S.K. Majumder	Web	IIT Guwahati	Select Introduction to Mass transfer operation Fick�s law of diffusion Steady state molecular diffusion in fluids under stagnant and laminar flow conditions Diffusion through variable cross-sectional area Diffusion coefficient: measurement and prediction Measurement of liquid-phase diffusion coefficient Multicomponent diffusion Diffusivity in solids and its applications Introduction to mass transfer coefficient Equimolar counter-diffusion of A and B (NA = -NB) Correlation for convective mass transfer coefficient Correlation of mass transfer coefficients for single cylinder Theories of mass transfer Penetration theory, Surface Renewal Theory, Boundary Layer Theory Interphase mass transfer theory Overall mass transfer coefficients Introduction Design of packed tower Design of packed tower based on overall mass transfer coefficient Counter-current multi-stage absorption (Tray absorber) Continuous contact equipment Absorption with chemical reaction Absorption accompanied by irreversible reactions Absorption resistance Introduction to Distillation Distillation columns and their process calculations Continuous distillation columns Analysis of binary distillation in trayed towers: McCabe-Thele Method Determination of the stripping section operating line (SOL) Analysis of binary distillation by Ponchon-Savarit Method Stepwise procedure to determine the number of theoretical trays Introduction to multicomponent Distillation Basic concepts Adiabatic saturation temperature Humidification and dehumidification operations and design calculations Mechanical Draft Towers: forced draft towers and induced draft towers Design calculations of cooling tower Key points in the design of cooling tower and Step-by-step design procedure of cooling tower Evaporation loss of water in cooling tower Example problems on humidification Example problems on dehumidification Special Module
103103036	Chemical Engineering	Molecular Simulations in Chemical Engineering	Dr. Ashok Kumar Dasmahapatra,Dr. Tamal Banerjee	Web	IIT Guwahati	Select Shrodinger Wave Equation for one electron system Shrodinger Wave Equation for Polyelectron system Slater Determinant and Basis Set Hatree Fock Theory Semi Empirical and Density Functional Theory Geometry Optimization Gaussian Job and Frequencies Benchmarking of Geometry Optimization Basics of Statistical Mechanics-I Basics of Statistical Mechanics-II Ideal Monoatomic gas and Canonical Ensemble Micro-canonical, Grand-canonical and Isobaric-Isothermal Ensemble Basics of Molecular Dynamics Force Field and Integrating Algorithms Periodic Box and Minimum Image Convention Long Range Forces Non-Bonded Interactions Estimation of Pure component Properties Steps involved in NAMD Input files in NAMD and VMD Introduction to Monte Carlo simulation and Monte Carlo Integration Monte Carlo Integration Random Number Generator Periodic Boundary Conditions (PBC) Equilibrations MC sampling Markov process and its applications - 1 Markov process and its applications - 2 Metropolis sampling Principles of detailed balance Simulation strategy NVT ensemble NVE and NPT ensemble GCMC - 1 GCMC - 2 GEMC MC simulation of polymers: fundamental Fundamental of polymer physics MC moves for polymer simulations Introduction to rare events Weighted Histogram Analysis Method (WHAM) and Umbrella sampling
103103037	Chemical Engineering	Process Control and Instrumentation	Dr. P.K. Saha	Web	IIT Guwahati	Select Introduction Process Modeling Example of Modeling of a Stirred Tank Heater Linearization of nonlinear model Laplace Transform Laplace Transform of derivatives First Order Process Significance of First Order Process Second Order Process Features of the process response Poles and Zeros Higher Order Systems Frequency Response Analysis Bode Diagram Bode Diagram of pure time delay Nyquist Plot Introduction to Feedback Control Process Transmission Lines Closed loop response of liquid level in a storage tank: A case study Offset in the output due to a P Controller Stability of a closed loop process Design of feedback controllers Cohen-Coon technique of Controller Tuning Stability of feedback control system Gain Margin and Phase Margin Problems with large dead time and/or inverse response Processes with inverse response Feed forward control Cascade Control Ratio Control Auctioneering Control Adaptive Control Introduction to Multi loop multivariable control Example of a flash drum for generating control configuration Interaction between control loops Decoupling of control loops Introduction to Instrumentation Process Flow Diagram Actuators Sensors Flow Measuring Devices Questions List Answers List
103104043	Chemical Engineering	Fluid Mechanics	Prof. Nishith Verma	Web	IIT Kanpur	Select Definition of a fluid and Newtons' law of viscosity Rate of strain, Non-Newtonian fluid Pascal's theorem, Basic equation Basic equation: derivation, pressure variation in an incompressible fluid Pressure variation in two immiscible fluids, manometer, barometer Calculation of vertical component Calculation of horizontal component, buoyancy Examples Lagrangian and Eulerian approaches; Euler's acceleration formula Steady and unsteady state Control mass, control volume, mass-, momentum-, kinetic energy balance Conservation of mass and examples Continuity, Momentum theorem Momentum theorem examples Equation of motion Couette and Poiseuille flows Tubular laminar flow and Hagen-Poiseuille equation Macroscopic momentum balance for pressure-drop in a tubular flow Mechanical energy balance Bernoulli equation and energy applications Minor loss, kinetic energy correction factor Flow measuring devices Major loss in pipe flow Examples on Bernoulli equation Centrifugal pump: characterisitcs, efficiency, NPSH Creeping flow, Stokes-law and terminal velocity Flow at high Reynolds numbers (Boundary layer theory) Examples on drag Drag, particles settling Pressure-drop: Ergun's equation Examples on pressure drop calculations Fluidization Minimum fluidization velocity Examples on fixed and fluidized beds Plate and frame press filter, Rotary filter Principles of filtration, constant pressure and volume filtration Example Buckingham Pi-theorem Geomteric and dynamic similarities, examples Equipment, flow patterns, power requirement Equipment, theoretical cut diameter, efficieny
103104044	Chemical Engineering	Fluid Mechanics	Dr. V. Shankar	Video	IIT Kanpur	Select Lecture-01 Lecture-02 Lecture-03 Lecture-04 Lecture-05 Lecture-06 Lecture-07 Lecture-08 Lecture-09 Lecture-10 Lecture-11 Lecture-12 Lecture-13 Lecture-14 Lecture-15 Lecture-16 Lecture-17 Lecture-18 Lecture-19 Lecture-20 Lecture-21 Lecture-22 Lecture-23 Lecture-24 Lecture-25 Lecture-26 Lecture-27 Lecture-28 Lecture-29 Lecture-30 Lecture-31 Lecture-32 Lecture-33 Lecture-34 Lecture-35 Lecture-36 Lecture-37 Lecture-38 Lecture-39 Lecture-40
103104045	Chemical Engineering	Introduction to Colloid and Interface Science and Engineering	Prof. A. Sharma	Web	IIT Kanpur	Select Lecture1 Lecture2 Lecture3 Lecture4 Lecture5 Lecture6 Lecture7 Lecture8 Lecture9 Lecture10 Lecture11 Lecture12 Lecture13 Lecture 14 Lecture15 Lecture16 Lecture17 Lecture18 Lecture19 lecture20 Lecture21 Lecture22 Lecture23 Lecture24 Lecture25 Lecture26 Lecture27 Lecture28 Lecture29 Lecture30 Lecture31 Lecture32 Lecture33 Lecture34 Lecture35 Lecture36 Lecture37 Lecture38 Lecture39 Lecture40
103104046	Chemical Engineering	Mass Transfer II	Prof. Nishith Verma	Video	IIT Kanpur	Select Lecture-01 Lecture-02 Lecture-03 Lecture-04 Lecture-05 Lecture-06 Lecture-07 Lecture-08 Lecture-09 Lecture-10 Lecture-11 Lecture-12 Lecture-13 Lecture-14 Lecture-15 Lecture-16 Lecture-17 Lecture-18 Lecture-19 Lecture-20 Lecture-21 Lecture-22 Lecture-23 Lecture-24 Lecture-25 Lecture-26 Lecture-27 Lecture-28 Lecture-29 Lecture-30 Lecture-31 Lecture-32 Lecture-33 Lecture-34 Lecture-35 Lecture-36 Lecture-37 Lecture-38 Lecture-39 Lecture-40
103104047	Chemical Engineering	Mechanics of Soft Materials	Dr. A. Ghatak	Web	IIT Kanpur	Select Displacement: Stress Work and Energy Loading on an elastic half space Rigid Flat Punch Pressure Applied to a circular region: Pressure Applied to a circular region(contd..) Hertzian Mechanics JKR Contact Mechanics Theory JKR Contact Mechanics Theory(contd...) Compression of an elastic film sandwiched between two rigid parallel plates Bending of a rod by couples applied at its end equations of equilibrium of rods Bending of a rod under concentrated load Torsion of Rods Bending of thin plates Longitudinal deformation of plates Wrinkling of a thin sheet under uni-axial tensile strain Peeling a thin flexible plate off an elastic adhesive bonded to a flexible substrate Peeling a thin flexible plate off an elastic adhesive bonded to a flexible substrate Elastic effect induced by surface tension of liquid. Neo-Hookean elasticity Homogeneous Strain Simultaneous Stretching and torsion of a solid neo-Hookean Cylinder Inflation of a baloon Theory of Incremental Stresses Theory of Incremental Stresses (contd...) Boundary Condition The slide modulus Buckling of a thick slab Stress induced surface instability of soft materials Estimation of flexural rigidity of proteinaceous filaments like microtubules and Actin. Estimation of flexural rigidity of proteinaceous filaments like microtubules and Actin. (continued ) The significance of the persistence length Chain configurations and elasticity Entropic Elasticity Six fold Network in 2D Network with six-fold symmetry under stress Network with six-fold symmetry at non-zero temperature (contd...) Three dimensional networks
103104049	Chemical Engineering	Plantwide Control of Chemical Processes	Dr. Nitin Kaistha	Web	IIT Kanpur	Select introduction Essential Process Control Basics Control of Common Unit Operations Issues in Plantwide Control System Design Economic Plantwide Control Design Procedure and Case Studies Comprehensive Case Study
103104050	Chemical Engineering	Plantwide Control of Chemical Processes	Dr. Nitin Kaistha	Video	IIT Kanpur	Select Lecture-01.Introduction to the course Lecture-02.Process Dynamics and Negative Feedback Lecture-03.PID control Lecture-04.Common Industrial Control Loops and advanced loops Lecture-05.Advanced loops (contd) and multivariable systems Lecture-06.Systematic Tuning Using Frequency Domain Analysis Lecture-07.Frequency Domain Analysis Lecture-08.Multivariable Systems Lecture-09.RGA and dynamic decoupling Lecture-10.Model based control Lecture-11.Dynamic Matrix Control Lecture-12.Control of Distillation Columns Lecture-13.Temperature inferential distillation control Lecture-14.Considerations in temperature inferential control Lecture-15.Control of Complex Column Configurations Lecture-16.Control of Heat Integrated Columns Lecture-17.Homogenous extractive distillation Lecture-18.More on complex columns and reactive distillation Lecture-19.Control of reactors Lecture-20.PFR controls (continued) & CSTRs Lecture-21.CSTR heat management Lecture-22.Heat Exchangers and Miscellaneous Systems Lecture-23.Degrees of freedom analysis Lecture-24.Degrees of freedom (contd) Lecture-25.Illustration of considerations in control structure synthesis Lecture-26.Two column recycle process Lecture-27.Throughput manipulator selection Lecture-28.Plantwide control structure design Lecture-29.Systematizing plantwide control design Lecture-30.The Luyben design procedure Lecture-31.Role of equipment capacity constraints Lecture-32.Recycle process case study Lecture-33.Recycle process case study (contd) Lecture-34.C4 isomerization process case study Lecture-35.C4 isomerization process case study (contd) Lecture-36.C4 isomerization process case study Lecture-37.Systematic economic plantwide control design procedure Lecture-38.Ethyl benzene process case study Lecture-39.C4 isomerization process revisited Lecture-40.Contrasting conventional and top-down approach Lecture 41.Cumene process plantwide control
103105052	Chemical Engineering	Advanced Heat and Mass Transfer	Dr. Saikat Chakraborty	Web	IIT Kharagpur	Select Equation of Continuity Conservation of Linear Momentum and Conservation of Mechanical energy Conservation of Energy for a Pure Substance Fouriers Law of Heat Conduction Conservation of Mass for each species & Ficks Law The Equation of Continuity for a Binary Mixture Heat Transfer in Extended surfaces (Fins) Performance of Fins Mass Transfer with Chemical Reaction Case Study: Low Pressure Chemical Vapor Deposition (LPCVD) Simultaneous Mass Diffusion and Reaction between wafers in Low Pressure Chemical Vapor Deposition Heat Conduction in semi-infinite Slab with Constant wall Temperature Heat Conduction in Semi-infinite Slab with Constant Flux density at the wall Semi-infinite Slab with timevarying surface temperature: Theory Semi-infinite Slab with time-varying surface temperature: Examples Heating of a finite slab Cooling of a Sphere in contact with a Well-Stirred Fluid & Heat Conduction in Solids with Interfacial Resistance Gas Absorption with Chemical Reaction Melting and Solidification (An example of Moving Boundary problem) Simultaneous Heat and Mass Transfer Fog formation Unsteady-state Evaporation Convective Transport: Fluid Flow to a Rotating Disk (in an infinite mass of fluid) Mass Transfer to a Rotating Disk Laminar Boundary Layers Heat Transfer to Boundary Layers Heat Transfer to Boundary Layers (Continued)1 Heat Transfer to Boundary Layers (Continued)2 Heat Transfer to Boundary Layers (Continued)3 Application of Mises Transformation to the problem of Mass Transfer from a sphere in Creeping (Stokes) flow Convective Transport in channels A Graetz-Nusselt Problem: Fully developed V, developing C or T Dispersion Dispersion (Continued) Multi-component Mixtures Binary Systems Thermal, Forced and Pressure Diffusion Solving the Multi-component Flux Equations Dimensional Analysis Transport in Turbulent Flow: Universal Velocity Profile Turbulent Flow in a Pipe
103105054	Chemical Engineering	Biochemical Engineering	Dr. Rintu Banerjee,Dr. Saikat Chakraborty	Video	IIT Kharagpur	Select Fundamentals of Biology & Biotechnology Glimpses of Microbial World - Bacteria Virus and Cell Organelles Carbohydrate Nucleic Acid Lipids Proteins Biochemistry & Thermodynamics of Enzymes Enzyme Kinetics : Michealis-Menten Kinetics Regulation of Enzyme Activity : Inhibition Regulation of Enzyme Activity : Inhibition (Contd.) Effects of Substrate and Inhibition, pH and Temperature on Enzyme Activity Immobilized Enzymes Immobilized Enzymes (Contd.) Interphase Mass Transfer and Reaction in Immobilized Enzymes Interphase Mass Transfer and Reaction in Immobilized Enzymes (Contd.) Effectiveness Factor in Immobilized Enzymes Bioenergetics and Glycolysis TCA Cycle Electron Transport Chain & Oxidative Phosphorylation Pentose Phosphate Pathways Glycogenesis & Glycogenolysis Urea Cycle, Gluconeogenesis and Glyoxalate Cycle Microbial Growth : Phases and Models Effect of Mass Transfer on Microbial & Fungal Growth Effect of Multiple Substrates and Inhibition on Microbial Growth Design of Bioreactors Design of Chemostats Stability of Bioreactors Stability of Bioreactors (Contd.) Introduction to Receptor - Ligand Binding Effects of Ligand Depletion and Multiple Receptors on Binding Kinetics Effects of Ligand Depletion and Multiple Receptors on Binding Kinetics (Contd.) Receptors-Mediated Endocytosis Kinetics of Receptor-Mediated Endocytosis General Model for Receptor-Mediated Endocytosis Multiple Interacting Microbial Population: Prey-Predator Models Manufacture of Biochemicals Manufacture of Biochemicals (Contd.) & Strategies for Biomolecules Separation Strategies for Biomolecules Separation (Contd.) Strategies for Biomolecules Separation (Contd.)
103105057	Chemical Engineering	Microscale Transport Processes	Prof. S. Dasgupta,Dr. Somnath Ganguly	Video	IIT Kharagpur	Select Introduction Introduction (Contd.) Lab on Chip Lab on Chip (Contd.) Microscale manufacturing practices Photolithography Photolithography (contd.) Deposition Plastic microfluidic devices Mixing Micro Heat Pipes Mixing (contd.) Mixing (contd.) Micro Heat Pipes (contd.) Mixing (contd.) Dispersion Dispersion (contd.) Dispersion (contd.) Electrowetting Electro osmosis Electrowetting (contd.) Electro osmosis (contd.) Dielectrophoresis Dielectrophoresis (contd.) Dielectrophoresis (contd.) Scaling dimension and issues Slip flow Microstructured reactor Immiscible flow in microchannel Immiscible flow in microchannel (contd.) Immiscible flow in microchannel (contd.) Scaling dimension and issues (contd.) Immiscible flow in microchannel (contd.) Plastic device making Transport processes and their descriptions Convective fluid dynamics in microchannels Microfluidic networks Electrohydrodynamic atomization Electrohydrodynamic atomization (contd.) Interfacial phenomena in thin liquid films
103105058	Chemical Engineering	Multiphase Flow	Prof. Gargi Das,Prof. P.K. Das	Web	IIT Kharagpur	Select Introduction Estimation of Flow Patterns Estimation of Flow Patterns (Contd.) Estimation of Flow Patterns (Contd. ) Estimation of Flow Patterns ( Contd. ) Methods of Analysis Definitions and Common Terminologies Definitions and Common Terminologies (Contd.) Homogeneous Flow Model Homogeneous Flow Model (Contd.) Homogeneous Flow Model (Contd.) The One Dimensional Drift Flux Model The One Dimensional Drift Flux Model (Contd.) The One Dimensional Drift Flux Model (Contd.) The One Dimensional Drift Flux Model (Contd.) The One Dimensional Drift Flux Model (Contd.) The Separated Flow Model The Separated Flow Model (Contd.) The Separated Flow Model (Contd. ) The Separated Flow Model (Contd.) The Separated Flow Model (Contd.) The Separated Flow Model (Contd.) The Separated Flow Model (Contd.) The Separated Flow Model ( Contd.) The Separated Flow Model (Contd.) The Separated Flow Model (Contd.) Flow Regime Based Models Flow Regime Based Models (Contd.) Flow Regime Based Models ( Contd.) Flow Regime Based Models (Contd.) Flow Regime Based Models (Contd.) Two Phase Flow with Phase Change Two Phase Flow with Phase Change (Contd.) Parametric Measurement of Two Phase Flow Parametric Measurement of Two Phase Flow (Contd.) Parametric Measurement of Two Phase Flow (Contd.) Parametric Measurement of Two Phase Flow (Contd.) Parametric Measurement of Two Phase Flow (Contd.) Parametric Measurement of Two Phase Flow (Contd.) Parametric Measurement of Two Phase Flow (Contd.)
103105059	Chemical Engineering	Multiphase Flow	Prof. Gargi Das,Prof. P.K. Das	Video	IIT Kharagpur	Select Introduction Estimation of Flow Patterns Estimation of Flow Patterns (Contd.) Flow Pattern Maps Fascinating Taylor Bubbles Definitions and Common Terminologies Definitions and Common Terminologies (Contd.) Simple Analytical Models The Homogeneous Flow Theory The Homogeneous Flow Theory (Contd.) Compressible Flow A Recapitulation Compressible Flow A Recapitulation (Contd.) Choked Flow Condition for Homogeneous Flow Drift Flux Model Drift Flux Model (Contd.) Drift Flux Model (Contd. ) Drift Flux Model ( Contd.) Separated Flow Model Separated Flow Model (Contd. ) Separated Flow Model ( Contd. ) Separated Flow Model - Condition of Choking Separated Flow Model - Condition of Choking (Contd.) Separated Flow Model - Estimation of Frictional Pressure Drop and Void Fraction Separated Flow Model - Estimation of Frictional Pressure Drop and Void Fraction (Contd.) Separated Flow Model - Estimation of Frictional Pressure Drop and Void Fraction (Contd. ) Separated Flow Model - Estimation of Frictional Pressure Drop and Void Fraction ( Contd. ) Analysis of Specific Flow Regimes Analysis of Specific Flow Regimes (Contd.) Analysis of Specific Flow Regimes - Slug Flow (Contd.) Two Phase Flow with Phase Change - An Introduction to Boiling Heat Transfer Bubble Growth Different Types of Nucleation Ibullition from Hot Surfaces Cycle of Bubble Growth and Departure Heat Transfer in Different Regimes of Boiling Heat Transfer in Different Regimes of Boiling (Contd.) Critical Heat Flux , Film Boiling Measuerement Techniques for Two Phase flow Parameters Measuerement Techniques for Two Phase flow Parameters - Void Fraction Measurement Measuerement Techniques for Two Phase flow Parameters - Void Fraction Measurement (Contd.) Measurement Techniques for Two - Phase Flow Parameters - Estimation of Flow Patterns
103105060	Chemical Engineering	Novel Separation Processes	Prof. S. De	Web	IIT Kharagpur	Select Lecture 1 : Fundamentals of Separation Processes Lecture 1 :Various Separation Processes and Identification of Novel Separation Processes Lecture 1 :Membrane Based Separation Processes Lecture 2 :Membrane Based Separation Processes ( Continued) Lecture 3 : Membrane Based Separation Processes ( Continued) Lecture 4 : Membrane Based Separation Processes ( Continued) Lecture 5 : Membrane Based Separation Processes ( Continued) Lecture 6 : Membrane Based Separation Processes ( Continued) Lecture 7 : Membrane Based Separation Processes ( Continued) Lecture 8 : Membrane Based Separation Processes(Continued) Lecture 9 : Membrane Based Separation Processes(Continued) lecture 10 : Membrane Based Separation Processes(Continued) Lecture 12 : Membrane Based Separation Processes(Continued) Lecture 13 : Membrane Based Separation Processes(Continued) Lecture 14 :Membrane Based Separation Processes(Continued) Lecture 15 :Membrane Based Separation Processes(Continued) Lecture 16 :Membrane Based Separation Processes(Continued) Lecture 17 :Membrane Based Separation Processes(Continued) Lecture 18 : Membrane Based Separation Processes(Continued) Lecture 19 : Membrane Based Separation Processes(Continued) Lecture 20 : Membrane Based Separation Processes(Continued) Lecture 21 : Membrane Based Separation Processes(Continued) Lecture 1 - External Field Induced Membrane Separation Processes For Colloidal Particles Lecture 2 - External Field Induced Membrane Separation Processes For Colloidal Particles: (Continued) Lecture 3 - External Field Induced Membrane Separation Processes For Colloidal Particles:(Continued) Lecture 4 - External Field Induced Membrane Separation Processes For Colloidal Particles:(Continued) Lecture 5 - Solved Problems Lecture 5 - Solved Problems: (Continued) Lecture 1 : Gas Separation: Lecture 2 : Gas Separation:(Continued) Lecture 1 : Surfactant Based Separation Processes Lecture 2 - Surfactant Based Separation Processes: (Continued) Lecture 3 - Surfactant Based Separation Processes: (Continued) Lecture 4 - Surfactant Based Separation Processes: (Continued) Lecture 1 : Centrifugal Separation Processes Lecture 2 - Centrifugal Separation Processes:( Continued) Lecture 1 :Chromatographic Separation and Ion Exchange Lecture 2 - Chromatographic Separation and Ion Exchange: (Continued) Lecture 1 : Electrophoretic Separation Methods Lecture 1 : Supercritical Fluid Extraction Lecture 2 - Electrophoretic Separation Methods:(Continued) Lecture 2 : Electrophoretic Separation Methods:(Continued) Lecture 11 - Membrane Based Separation Processes: ( Continued)
103105061	Chemical Engineering	Novel Separation Processes	Prof. S. De	Video	IIT Kharagpur	Select Fundamentals of Separation Processes Identification of Novel Separation Processes Membrane Separation Processes Membrane Separation Processes (Contd...1) Membrane Separation Processes (Contd...2) Membrane Separation Processes (Contd...3) Membrane Separation Processes (Contd...4) Membrane Separation Processes (Contd...5) Membrane Separation Processes (Contd...6) Membrane Separation Processes (Contd...7) Membrane Separation Processes (Contd...8) Membrane Separation Processes (Contd...9) Membrane Separation Processes (Contd...10) Membrane Separation Processes (Contd...11) Membrane Separation Processes (Contd...12) Membrane Separation Processes (Contd...13) Membrane Separation Processes (Contd...14) Membrane Separation Processes (Contd...15) Membrane Separation Processes (Contd...16) Membrane Separation Processes (Contd...17) Membrane Separation Processes (Contd...18) External Field Induced Membrane Separation Processes External Field Induced Membrane Separation Processes (Contd...1) External Field Induced Membrane Separation Processes (Contd...2) External Field Induced Membrane Separation Processes (Contd...3) External Field Induced Membrane Separation Processes (Contd...4) Gas Separation Gas Separation (Contd.) Surfactant Based Separation Processes Surfactant Based Separation Processes (Contd.) Micellar Enhanced Ultrafiltration Micellar Enhanced Ultrafiltration (Contd.) Liquid Membranes Liquid Membranes (Contd.) Centrifugal Separation Processes Chromatographic Separation Processes Chromatographic Separation Processes (Contd.) Ion Exchange Processes Electrophoretic Separation Methods Electrophoretic Separation Methods (Contd.) Supercritical Fluid Extraction
103105066	Chemical Engineering	Instability and Patterning of Thin Polymer Films	Dr. R. Mukherjee	Video	IIT Kharagpur	Select Introduction Introduction (Contd.) Some Fundamental Surface Related Concepts - I Surface Tension (in terms of molecular interactions) Effect Surface Tension : Laplace Pressure Young Laplace Equation Rayleish Instability Meso Scale Fabrication Approaches Photo Lithography - I Photo Lithography - II Photo Lithography - III Photo Lithography - IV Photo Lithography - V Nano Imprint Lithography Nano Imprint Lithography (Contd.) Soft Lithography - I Soft Lithography - II Soft Lithography - III Soft Lithography - IV Soft Lithography - V Soft Lithography - VI Atomic Force Microscope - I Atomic Force Microscope - II Atomic Force Microscope - III Atomic Force Microscope - IV Atomic Force Microscope - V Intermolecular Forces between Particles and Surfaces - I Intermolecular Forces between Particles and Surfaces - II Intermolecular Forces between Particles and Surfaces - III Intermolecular Forces between Particles and Surfaces - IV Spontaneous instability and dwetting of thin polymer film - I Spontaneous instability and dwetting of thin polymer film - II Spontaneous instability and dwetting of thin polymer film - III Spontaneous instability and dwetting of thin polymer film - IV Spontaneous instability and dwetting of thin polymer film - V Spontaneous instability and dwetting of thin polymer film - VI Spontaneous instability and dwetting of thin polymer film - VII Template Guided Dewetting Elastic Contact Instability and Lithography Gradient Surfaces
103105106	Chemical Engineering	Advanced Mathematical Techniques in Chemical Engineering	Prof. S. De	Video	IIT Kharagpur	Select Introduction to vector space Introduction to vector space (Contd.) Onto, into, one to one function Vectors Vectors (Contd.) Contraction Mapping Contraction Mapping (Contd.) Matrix, Determinant Eigenvalue Problem in Discrete Domain Eigenvalue Problem in Discrete Domain (Contd.) Eigenvalue Problem in Discrete Domain (Contd.) Eigenvalue Problem in Discrete Domain (Contd.) Stability Analysis Stability Analysis (Contd.) Stability Analysis (Contd.) More Examples Partial Differential Equations Partial Differential Equations(Contd.) Eigenvalue Problem in Continuous Domain Special ODEs Adjoint Operator Theorems of Eigenvalues and Eigenfunction Solution PDE : Separation of Variables Method Solution of Parabolic PDE : Separation of variables method Solution of Parabolic PDE : Separation of Variables Method (Contd.) Solution of Higher Dimensional PDEs Solution of Higher Dimensional PDEs (Contd.) Four Dimensional Parabolic PDE Solution of Elliptic and Hyperbolic PDE Solution of Elliptic and Hyperbolic PDE (Contd.) PDE in Cylindrical and Spherical Coordinate Solution of non-homogeneous PDE Solution of non-homogeneous PDE (Contd.) Solution of non-homogeneous Parabolic PDE Solution of non-homogeneous Elliptic PDE Solution of non-homogeneous Elliptic PDE (Contd.) Similarity Solution Similarity Solution (Contd.) Integral Method Laplace Transform Fourier Transform
103106068	Chemical Engineering	Advanced Transport Phenomena	Dr. R. Nagarajan	Web	IIT Madras	Select Overview & �Bulb Blackening� Example Overview & �Hot Corrosion� Example Transport Laws: Assumptions & Control Volumes Conservation Principles: Mass Conservation Conservation Principles: Momentum & Energy Conservation Conservation Principles: Entropy Conservation Conservation Equations: Alternative Formulations Conservation Equations: Across Discontinuities, Turbulent Flows & Multiphase Flows Constitutive Laws: Momentum Transfer Constitutive Laws: Energy & Mass Transfer Constitutive Laws: Illustrative Problems Momentum Transport: Steady Compressible Fluid Flow Momentum Transport: Shock Waves Momentum Transport: Flow over a Solid Wall Momentum Transport: Steady Laminar Flow Momentum Transport: Flow in Porous Media & Packed Beds Momentum Transport: Illustrative Problems Energy Transport: Flow Past Hot Sphere Energy Transport: Steady-State Heat Conduction Energy Transport: Transient Heat Diffusion Energy Transport: Convective Heat Transfer Energy Transport: Analogy to Momentum Transfer Energy Transport: Radiation & Illustrative Problems Mass Transport: Ideal Reactors & Transport Mechanisms Mass Transport: Composite Planar Slab Mass Transport: Diffusion with Chemical Reaction Mass Transport: Two-Phase Flow Mass Transport: Non-Ideal Flow Reactors Mass Transport: Illustrative Problems Similitude Analysis: Dimensional Analysis Similitude Analysis: Full & Partial Similitude Analysis: Flame Flashback, Blowoff & Height Similitude Analysis: Illustrative Problems Problem Solving Techniques, Aids, Philosophy Illustrative Example: Flame Propagation Outline of Numerical Solution Methods Illustrative Example: Protective Oxide Dissolution on GT Blades Student Exercises: True/ False Questions Students Exercises: Numerical Questions (Modules 1-5) Students Exercises: Numerical Questions (Modules 6-8)
103106073	Chemical Engineering	Computational Fluid Dynamics	Prof. Sreenivas Jayanti	Video	IIT Madras	Select Motivation for CFD and Introduction to the CFD approach Illustration of the CFD approach through a worked out example Eulerian approach, Conservation Equation, Derivation of Mass Conservation Equation and Statement of the momentum conservation equation Forces acting on a control volume; Stress tensor; Derivation of the momentum conservation equation ; Closure problem; Deformation of a fluid element in fluid flow Kinematics of deformation in fluid flow; Stress vs strain rate relation; Derivation of the Navier-Stokes equations Equations governing flow of incompressible flow; Initial and boundary conditions; Wellposedness of a fluid flow problem 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. 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 Finite difference approximation of pth order of accuracy for qth order derivative; cross -derivatives; Examples of high order accurate formulae for several derivatives One -sided high order accurate approximations; Explicit and implicit formulations for the time derivatives Numerical solution of the unsteady advection equation using different finite difference approximations Need for analysis of a discretization scheme; Concepts of consistency, stability and convergence and the equivalence theorem of Lax ; Analysis for consistency Statement of the stability problem; von Neumann stability analysis of the first order wave equation Consistency and stability analysis of the unsteady diffusion equation; Analysis for two- and three -dimensional cases; Stability of implicit schemes 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 Template for the generic scalar transport equation and its extension to the solution of Navier-Stokes equa tions for a compressible flow. Illustration of application of the template using the MacCormack scheme for a three-dimensional compressible flow 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 Artificial compressibility method and the streamfunction-vorticity method for the solution of NS equations and their limitations Pressur e equation method for the solution of NS equations Pressure-correction approach to the solution of NS equations on a staggered grid; SIMPLE and its family of methods Need for effici ent solution of linear algebraic equations; Classification of approaches for the solution of linear algebraic equations. Direct methods for linear algebraic equations; Gaussian elimination method Gauss-Jordan method; LU decomposition method; TDMA and Thomas algorithm Basic iterative methods for linear algebraic equations: Description of point -Jacobi, Gauss-Seidel and SOR methods Convergence analysis of basic iterative schemes; Diagonal dominance condition for convergence; Influence of source terms on the diagonal dominance condition; Rate of convergence Application to the Laplace equation Advanced iterative methods: Alternating Direction Implicit Method; Operator splitting Advanced iterative methods; Strongly Implicit Proc edure; Conjugate gradient method; Multigrid method Illustration of the Multigrid method for the Laplace equation Overview of the approach of numerical solution of NS equations for simple domains; Introduction to complexity arising from physics and geometry Derivation of the energy conservation equation Derivation of the species conservation equation; dealing with chemical reactions Turbulence; Characteri stics of turbulent flow; Dealing with fluctuations and the concept of time-averaging Derivation of the Reynolds -averaged Navier -Stokes equations; identification of the closure problem of turbulence; Boussinesq hypothesis and eddy viscosity Reynol ds stresses in turbulent flow; Time and length scales of turbulence; Energy cascade; Mixing length model for eddy viscosity One-equation model for turbulent flow Two -equation model for turbulent flow; Numerical calculation of turbulent reacting flows Calculation of near-wall region in turbulent flow; wall function approach; near-wall turbulence models Need for special methods for dealing with irregular fl ow geometry; Outline of the Body-fitted grid approach ; Coordinate transformation to a general, 3-D curvilinear system Transformation of the governing equations; Illustration for the Laplace equation; Appearance and significance of cross -derivative terms; Concepts of structured and unstructured grids. Finite vol ume method for complicated flow domain; Illustration for the case of flow through a duct of triangular cross -section. Finite volume method for the general case Generation of a structured grid for irregular flow domain; Algebraic methods; Elliptic grid generation method Unstructured grid generation; Domain nodalization; Advancing front method for triangulation Delaunay triangulation method for unstructured grid generation 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.
103106074	Chemical Engineering	Computational Techniques	Dr. Niket S.Kaisare	Video	IIT Madras	Select Introduction Computational and Error Analysis Linear Equations Part 1 Linear Equations Part 2 Linear Equations Part 3 Linear Equations Part 4 Linear Equations Part 5 Linear Equations Part 6 Non Linear Algebraic Equations Part 1 Non Linear Algebraic Equations Part 2 Non Linear Algebraic Equations Part 3 Non Linear Algebraic Equations Part 4 Non Linear Algebraic Equations Part 5 Non Linear Algebraic Equations Part 6 Regression and Interpolation Part 1 Regression and Interpolation Part 2 Regression and Interpolation Part 3 Regression and Interpolation Part 4 Regression and Interpolation Part 5 Differentiation and Integration Part 1 Differentiation and Integration Part 2 Differentiation and Integration Part 3 Differentiation and Integration Part 4 Differentiation and Integration Part 5 Ordinary Differential Equations (initial value problems) Part 1 Ordinary Differential Equations (initial value problems) Part 2 Ordinary Differential Equations (initial value problems) Part 3 Ordinary Differential Equations (initial value problems) Part 4 Ordinary Differential Equations (initial value problems) Part 5 Ordinary Differential Equations (initial value problems) Part 6 Ordinary Differential Equations (initial value problems) Part 7 Ordinary Differential Equations (initial value problems) Part 8 Ordinary Differential Equations (initial value problems) Part 9 Ordinary Differential Equations (boundary value problems) Part 1 Ordinary Differential Equations (boundary value problems) Part 2 Ordinary Differential Equations (boundary value problems) Part 3 Partial Differential Equations Part 1 Partial Differential Equations Part 2 Partial Differential Equations Part 3 Partial Differential Equations Part 4
103106075	Chemical Engineering	Introduction to Microelectronic Fabrication Processes	Dr. S. Ramanathan	Web	IIT Madras	Select Lecture 1: Introduction Lecture 2: Lithography- Layout and Mask Lecture 3: Lithography- Basic process Lecture 4: Lithography- Basic process (continued) Lecture 5: : Advanced lithography Lecture 6: : Advanced lithography-II Lecture 7: Lithography-production details, next generation lithography Lecture 8: : Physical Vapor Deposition Lecture 9: : Physical Vapor Deposition - continued Lecture 10: : Physical Vapor Deposition and Chemical Vapor Deposition Lecture 11: Chemical Vapor Deposition - continued Lecture 12: Chemical Vapor Deposition, Electrochemical Deposition, Spin-on coating Lecture 13: Wet etching Lecture 14: Dry etching Lecture 15: Dry etching Continued Lecture 16: Chemical Mechanical Planarization (CMP) Lecture 17: CMP continued Lecture 18: Band Structure Lecture 19: Diodes Lecture 20: MOS transistor structure and operation Lecture 21: MOS transistor (continued) Lecture 22: MOS transistor Processing Lecture 23: MOS transistor fabrication and isolation Lecture 24: Diffusion basics & Constant source diffusion Lecture 25: Limited source diffusion Lecture 26: Diffusion- production issues Lecture 27: Ion implantation - basics Lecture 28: Ion implantation � non idealities Lecture 29: Oxidation - basics Lecture 30: Oxidation - Modeling Lecture 31: BEOL issues and Aluminum metallization Lecture 32: Electromigration and copper metallization Lecture 33: Testing Basics Lecture 34: FBM Lecture 35: Yield and defects - basics Lecture 36: Yield models and data analysis Lecture 37: Yield analysis Lecture 38: Yield analysis - continued Lecture 39: Scanning electron microscopy Lecture 40: SEM (continued) and atomic force microscopy Lecture 41: AFM (Continued) and Ellipsometry
103106078	Chemical Engineering	System (Process) Identification	Dr. Arun K.Tangirala	Web	IIT Madras	Select Introduction and Scaling Step-wise procedure for identification A quick tour of Identification Mathematical descriptions of systems (models) Non-Parametric Descriptions Parametric Descriptions State-Space Descriptions Sampled-Data Systems Random Variables Covariance & Correlation Introduction to Random Processes Auto-Correlation & Cross-Correlation Functions Moving Average Models Auto-Regressive Models ARIMA Models Spectral Representations Introduction to Estimation Properties of estimators - I Properties of estimators - II Estimation methods: MoM, OLS methods Estimation methods: Variants of OLS Estimation methods: MLE, Bayesian methods Estimation of Signal Properties Overall Models for Identification Predictions Estimation of Time-Series Models Estimation of Impulse / Step (Response) Models Estimation of Frequency Response Functions Estimation of Parametric Input-Output Models State-Space Models Sub-space Identification Algorithms Model Structure Selection & Assessment Case Studies Identifiability & Informative Experiments Inputs for identification of LTI systems Recursive Identification Closed-Loop Identification
103106101	Chemical Engineering	Nuclear Reactor Technology	Dr. K.S. Rajan	Web	IIT Madras	Select Introduction to Reactor System Three Stage Indian Nuclear Programme Classification of Reactors Core Configuration & Cycle diagram of Pressurized Water Reactor Core Configuration & Cycle diagram of Boiling Water Reactor Pressurized Heavy Water Reactor Gas-Cooled Reactor, Advanced Heavy Water Reactor & Fast Reactor Comparison of different fuel materials Selection of Materials for Reactor Internals Principles of heat generation in thermal reactors Heat Removal from Reactor Systems Heat flow and temperature distribution in plate fuel elements Neutron flux profile in cylindrical fuel elements Heat flow and temperature distribution in cylindrical fuel elements Heat flow and temperature distribution in cylindrical fuel elements. Primary heat transport system: Steam generators, Shutdown cooling Emergency Core Cooling System Moderator & Moderator System Auxiliary systems Secondary Systems: Steam System Secondary Systems: Condensate/Feedwater Cycle Reactivity Balance & Reactor Control System Reactor Control System & Shutdown mechanisms Neutron Spectrum & Cross sections FBR Neutronics: Core and Blanket Characteristics FBR Neutronics: Breeding potential, Breeding Ratio, Breeding Gain and Doubling time Breeding Breeders an inexhaustible energy source Characteristics and types of fast reactors Comparison of characteristics of fast and thermal reactors, Role of fast reactors in Indian Nuclear Programme General features of Fast Reactor Core Requirement and Choice of Core Materials Requirement and Choice of core materials. Design constraints - Maximum clad temperature, linear power rating Design constraints - Maximum allowable coolant velocity Design constraints - Outlet temperature of coolant & pressure drop Introduction to sodium technology - Physical properties of sodium Introduction to sodium technology - Neutronic characteristics of sodium and complexities Introduction to Sodium Technology - Heat Transport System (Primary Circuit) Introduction to Sodium Technology - Heat Transport System (Secondary Circuit) |
103106103	Chemical Engineering	Particle Characterization (PG)	Dr. R. Nagarajan	Video	IIT Madras	Select Introduction: Why study particle characterization? Introduction: Classification of particle characteristics Morphological Characterization: Shape analysis methods Morphological Characterization: Techniques of shape assessment Morphological Characterization: Decision rules Morphological Characterization: Static vs dynamic methods of size analysis Morphological Characterization: Static methods of size analysis Morphological Characterization: Light scattering from spherical particles Morphological Characterization: Particle counters Morphological Characterization: Particle size distributions Morphological Characterization: Acoustic Attenuation Spectroscopy Morphological Characterization: Nano-particle size analysis Structural Characterization Interfacial Characterization Surface Adhesion: Forces Surface Adhesion: Electrostatic & Surface-Tension Forces Surface Adhesion: Adhesion Force Measurement Particle Removal: Methods Particle Removal: Wet Cleaning Particle Cohesion: Forces Particle Cohesion: Flowability Implications Transport Properties: Diffusion & Electrostatic Field Effects Transport Properties: Drag & Inertia Transport Properties: Deposition Fluxes & Rates Transport Properties: Illustrative Application Chemical & Compositional Characterization: Reactivity Chemical & Compositional Characterization: Analytical Methods Chemical & Compositional Characterization: XRD & AFM Nano-particle Characterization: Bottom-Up Synthesis Methods Nano-particle Characterization: Top-Down Synthesis Methods Nano-particle Characterization: Dispersion Nano-particle Characterization: Properties & Techniques Practical Relevance of Particle Characterization: Nano-Fluids Practical Relevance of Particle Characterization: Filtration Practical Relevance of Particle Characterization: Cleanrooms Practical Relevance of Particle Characterization: High-Technology Manufacturing Practical Relevance of Particle Characterization: Explosivity Practical Relevance of Particle Characterization: Environment & Human Health Practical Relevance of Particle Characterization: Other Applications Summary
103106108	Chemical Engineering	Heavy and Fine Chemicals (Chemical Process Technology)	Dr. Nirmal K. Patel	Web	IIT Madras	Select HEAVY AND FINE CHEMICALS CARBON DIOXIDE OXYGEN AND NITROGEN HYDROGEN HYDROGEN (Continued) AMMONIA ACETYLENE SODIUM CHLORIDE SODIUM CARBONATE SODIUM CARBONATE (continued) SODIUM BICARBONATE SODIUM HYDROXIDE SODIUM HYDROXIDE (Continued) SODIUM HYDROXIDE (Continued.) CHLORINE NITRIC ACID SULFURIC ACID SULFURIC ACID (continued) HYDROCHLORIC ACID PHOSPHOROUS PHOSPHORIC ACID CEMENT INDUSTRIES CEMENT CLASSIFICATION (Continued) CEMENT MANUFACTURE CEMENT (Continued) CERAMIC INDUSTRIES WHITEWARES CLAY PRODUCTS AND REFRACTORIES SPECIALIZED CERAMIC PRODUCTS AND VITREOUS ENAMEL GLASS INDUSTRIES MANUFACTURE OF GLASS GLASS (Continued) FERTILIZER AMMONIUM PHOSPHATE SUPERPHOSPHATE TRIPLE SUPERPHOSPHATE UREA CALCIUM AMMONIUM NITRATE AMMONIUM CHLORIDE AMMONIUM SULFATE POTASSIUM CHLORIDE POTASSIUM SULFATE PAINT INDUSTRIES PAINT INDUSTRIES (continued) PAINT INDUSTRIES (continued.)
103106109	Chemical Engineering	Chemical process industries	Dr. Nirmal K. Patel	Web	IIT Madras	Select Overview Material of construction Safety and waste disposal Safety and waste disposal(Contd) Acetic acid Acetic acid(contd) Formic acid Benzoic acid Phthalic acid Oxalic acid Fermentation industries Fermentation industries(contd) Industrial alcohol Absolute alcohol Butyl alcohol Glycerol Glycerol(contd) Ethylene glycol Propylene glycol Sodium thiosulfate Sodium bromide Sodium sulfate Sodium sulfite Fluorine Bromine Iodine Chlorine Chlorine(contd) Chloroform Carbon tetrachloride Silicon carbide Calcium carbide Dimethyl formamide Dimethyl sulfoxide Tetrahydro furan Dimethyl ether Diethyl ether
103107082	Chemical Engineering	Chemical Technology - I	Dr. I.D.Mall	Web	IIT Roorkee	Select Chemical Process Industries Raw Material for Organic Chemical Industries Basic Principles of Unit Processes & Unit Operations in Organic Chemical Industries Coal as Chemical Feed Stock Coal carbonization and Coke Oven Plant Gasification of Coal, Petrocoke and Biomass Introduction to Pulp and Paper Industry, Raw Material for Paper Industry and Technological Development Pulping and Bleaching Recovery of Chemicals from Kraft and Agrobased Mills Stock Preparation and Paper Making Introduction to Soap and Detergent, Soap Making and Recovery of Glycerine Synthetic Detergent and Linear Alkyl Benzene Introduction to Sugar , Fermentation Industry and Manufacture of Alcohol Ethanol as Chemical Feedstock Introduction : Status of Petroleum Refinery, Crude Oil and Natural Gas Origin, Occurrence, Exploration, Drilling and Processing, Fuel Norms Evaluation of Crude Oil, Petroleum Products and Petrochemicals Crude Oil Distillation Thermal Cracking, Visbreaking and Delayed Coking Catalytic Cracking, Fluid Catalytic Cracking and Hydro Cracking Catalytic Reforming Alkylation, Isomerisation and Polymerisation Desulphurisation Processes and Recovery of Sulphur Profile of Petrochemical Industry and its Structure Naphtha and Gas Cracking for Production of Olefins Recovery of Chemicals from FCC and Steam Cracker Synthesis Gas and its Derivatives: Hydrogen, CO, Methanol, Formaldehyde, Metanol to Olefin Technology Ethylene and Derivatives: Ethylene Oxide, Ethylene Glycol, Ethylene Dichloride and Vinyl Chloride, Acetaldehyde Propylene, Propylene Oxide and Isopropanol, Acrylonitrile Aromatic (BTX) Production Aromatics Product Profile, Ethyl benzene &Styrene, Cumene and Phenol, Bisphenol, Aniline Introduction to Polymer, Elastomer and Synthetic Fibre, Classification Polymerisation Reactions and Polymer Polymer: Polyolefins: Polyethylene, Poly Propylene and Polystyrene Polyvinyl chloride, Polycarbonate, Thermoset Resin:Phenol Formaldehyde, Urea Formaldehyde and Melamine Formaldehyde Elastomers: Natural and Synthetic Rubber , Styrene Butadiene Rubber(SBR), Poly Butadiene, Nitrile Rubber Cylohexane, Caprolactam, Nylon 6 Adipic Acid and Hexametrhylenediamine, Nylon66 DMT and Terephthalic Acid, Polyester, PET Resin, PBT Resin Acrylonitrile, Acrylic Fibre, Modified Acrylic Fibre, Polyurethane Cellulosic Fibre(Viscose Rayon and Acetate Rayon, Cuprammoium rayon) Agrochemical Market Dyes and Intermediate
103107084	Chemical Engineering	Environmental Engineering	Dr. V. C. Srivastava	Web	IIT Roorkee	Select Introduction to Environmental Engineering Environmental Acts and Rules Standards for ambient air, noise emission and effluents Water Quality Monitoring: Collection of water samples & estimation of physical parameters Water Quality Monitoring: Estimation of Chemical parameters Water Quality Monitoring: Estimation of alkalinity, BOD & COD Water Quality Monitoring: Estimation of fecal indicator bacteria Characterization of Air Emissions Fugitive Emission Control and Water Use Minimization Water Recycling and Reuse Introduction to Air Pollution and Control Particulate Emission Control by Mechanical Separation & Wet Gas Scrubbing Design of cyclones Design of fabric filter Particulate emission control by electrostatic precipitation Design of ESP Gaseous emission control by absorption and adsorption-1 Introduction to Water Pollution and Control Pre-treatment & Physical treatment: Flow equalization Pre-treatment & Physical treatment: Aeration Part 1 Pre-treatment & Physical treatment: Aeration Part 2 Pre-treatment & Physical treatment: Coagulation and flocculation � Part 1 Pre-treatment & Physical treatment: Coagulation and flocculation � Part 2 Setting and Sedimentation: Part 1 Setting and Sedimentation: Part 2 Settling Chamber Design Filtration Water Pollution Control By Membrane Based Technologies Water Pollution Control by Adsorption: Part 1 Water Pollution Control by Adsorption: Part 2 Electrochemical Treatment Introduction to Biological Treatment Anaerobic and Aerobic Treatment Biochemical Kinetics Activated sludge and lagoons Trickling filter Sequential Batch Reactor UASB Reactor Municipal and Solid Waste Disposal Plastic Waste Management: Part I Plastic Waste Management: Part II Solids Waste Disposal � Composting Landfilling Gasification and incineration Gaseous Emission Control by Absorption-2 Sludge Separation and Drying
103107086	Chemical Engineering	Fertilizer Engineering	Dr. Amit Dhiman	Web	IIT Roorkee	Select Introduction to Plant nutrients, Fertilizer specifications, Terminology and Definitions Classifications of Soil nutrients and Fundamentals of Soil Nitrogen Fundamentals of Soil Phosphorus, Soil Potassium and Soil Sulfur Ammonia: Production and Storage - Part 1 Ammonia: Production and Storage - Part 2 Nitric acid � Part 1 Nitric acid � Part 2 Ammonium Nitrate Production of Straight Granulated AN and CAN Ammonium Sulphate Calcium Nitrate Ammonium chloride Urea � Part 1 Sulphuric acid Sulphuric Acid � Part 2 Phosphoric acid � Part 1 Production Processes of Phosphoric acid Single supephosphate Triple Superphosphate Ammonium Phosphates Nitrophosphate Fertilizers � Part 1 Nitrophosphate Fertilizers � Part 2 Other Phosphate Fertilizers � Part 2 Potash Fertilizers Potash Fertilizers - Potassium Sulphate Potash Fertilizers - Potassium Nitrate Compound Fertilizers: Part 1 Compound Fertilizers: Part 2 Processes for manufacturing compound fertilizers � Part 1 Unique requirements for manufacturing urea based granular composed fertilizers NPK Fertilizers � Mixed Acid route NPK Fertilizers � Nitrophosphate Route Environmental Issues Related to the Use of Fertilizers Impact of Fertilizers on the environment Environmental Impact of the Fertilizer Industry � Part 1 Environmental Impact of the Fertilizer Industry � Part 2 Environmental impact of Solid Fertilizer Industry
103107088	Chemical Engineering	Food Engineering	Dr. Shishir Sinha	Web	IIT Roorkee	Select Introduction to Food Technology World's Food Demand Food demand scenario in India nutrition Food additives Deteriorative factors and their control preliminary food processing methods Steam Process controls in food processing Heating and cooling systems for foods Thermophysical Properties INDIRECT CONTACT FREEZING SYSTEMS Freezing Fruits and Vegetables Freezing time Refrigeration Thermal Death time Food preservation frying Food preservation by Irradiation preservation food by concentration Microwave heating fermentationt Food Preservation By Pickling electrodialysis membrane separation Reverssmosis dehydration Production of Food Products Food Production Methods production of alcoholic Dairy Products Meat Poultry Intro Food Processing FOOD PROCESSING 2 FOOD PROCESSING WASTES Food_Spoilage packaging canning canning procedure Heat Sterilization
103107094	Chemical Engineering	Process Integration	Dr. B. Mohanty	Web	IIT Roorkee	Select Process Integration - the inherent concepts process integration, methods and areas of Application Fundamental concepts related to heat integration Hot Composite Curves Cold Composite Curves Hot and Cold Composite Curves and �The Pinch Threshold Problems Graphical representations used in Pinch Analysis Energy Targeting Procedure Problem Table Algorithm-1st Part Grand composite curve Problem Table Algorithm �2nd Part No of units Target Shell Targeting-1st Part Shell Targeting- 2nd Part Area Targeting -1st Part Area Targeting-2nd Part Area Targeting-3rd Part Cost Targeting Supertargeting-optimization of ?Tmin ?P targeting and supertargeting Global & Stream specific ?Tmin and its relevance Rules for Pinch Design Method (PDM) -1st part Rules for Pinch Design Method (PDM) -2nd part Application of PDM for MER HEN synthesis Design for threshold problems Design for single pinch problems Design for multi pinch problems HEN optimization Remaining Problem analysis Driving Force Plot Low Temperature process Design Combined Heat and Power Design (using steam turbine) Integration of Gas turbine with process-1st Part Integration of Gas turbine with process-2nd Part Placement and Integration of Distillation Column Heat Integration of evaporators Integration of heat pump Data Extraction Placement of Heat Engine, Heat pump and Reactors Integration of Furnace Topology Trap Area Targeting-4th Part
103107096	Chemical Engineering	Process Modelling and Simulation	Dr. V. K. Agrawal	Web	IIT Roorkee	Select Simulation & IFD IFD to numerical form planning and calculation Theroritical models and parameter estimation Parameter estimation in theoritical models Parameter estimation in differential equation models- numerical methods MODELS AND THEIR CLASSIFICATION Maximum Gradient Description Population Balance Models Experimental Measurement of Age Distribution Function General Population Balance Combined Models PROBABLISTIC MODELS Curve Fitting Basic Models of Flow systems MULTIPLE GRADIENT DESCRIPTION MACROSCOPIC DESCRIPTION ALTERNATE CLASSIFICATION OF TRANSPORT PHENOMENA MODELS Basic Models of Mixing Systems Basic Models of Simultaneous Heat and Mass Transfer MATHEMATICAL MODELLING OF EVAPORATOR MULTIPLE EFFECT EVAPORATOR SYSTEM ANALYSIS AND MODELING OF EVAPORATORS USING NEWTON RAPHSON�S METHOD (Without Boiling Point Rise) MODELLING OF MULTIPLE EFFECT EVAPORATORS WITH BOILING POINT RISE DISTILLATION Mathematical modeling of Continuous distillation Column Approximate Methods For Multicomponent Multistage Separations Minimum Stages calculation for multicomponent distillation column Separation of multicomponent mixtures by use of conventional distillation column with multiple stages Application of the ? method of convergence, the Kb method, and the constant-composition method for multicomponent distillation column Multicomponent Vapor - Liquid Cascades Absorber and stripper CALCULATION PROCEDURES FOR SOLVING FOR ABSOBER AND STRIPPING PROBLEM PROCEDURE I: SINGLE? METHOD OF CONVERGENCE The Sujata method Extraction MATHEMATICAL MODELING OF CHEMICAL REACTORS Fixed bed reactors Two dimensional model with void age and velocity profiles Fluidized Bed Reactors Trickle Bed Reactors
103108097	Chemical Engineering	Chemical Reaction Engineering	Prof. Jayant M Modak	Video	IISc Bangalore	Select Introduction & Overview Basic concepts : Representation of Chemical Reactions Thermodynamics of Chemical Reactions: Part I Thermodynamics of Chemical Reactions: Part II Chemical Reaction Kinetics - Overview Chemical Reaction Kinetics & Reactor Design Chemical Reactor Design Problem Solving: Thermodynamics & Kinetics Complec Reactions - Introduction Complec Reactions - Yield & Selectivity Complex Reactions - Quasi Steady State and Quasi Equilibrium Approximations Complex Reactions - Kinetics of Chain Reactions & polymerization Catalytic reactions - Introduction Catalytic reactions - Adsorption & Desorption Catalytic reactions - Kinetics Monomolecular Reaction Network & Lumping Analysis Problem solving: Complex reactions Gas-solid Catalytic Reactions - External diffusion Gas-solid Catalytic Reactions - Transport in Catalyst Pellet Gas-solid Catalytic Reactions - Diffusion & Reaction I Gas-solid Catalytic Reactions - Diffusion & Reaction II Gas-solid Catalytic Reactions - Diffusion & Reaction III Gas-solid Catalytic Reactions - Nonisothermal effects Gas-solid Noncatalytic Reactions Gas-Liquid Reactions Problem solving: Heterogenous reactions Chemical Reactor Design: Mass & Energy Balances Chemical Reactor Design: Mass & Energy Balances for Heterogenous Reactions Nonisothermal Reactor Operation Case Study - Ethane dehyrogenation Case Study - Hydrogenation of Oil Case Study - Ammonia Synthesis Autothermal reactors Parametric Sensitivity CSTR - multiple steady states Stability Analysis - Basics Stability Analysis - Examples Nonideal flow and reactor performance - I Nonideal flow and reactor performance - II Problem solving: Reactor Design
103108098	Chemical Engineering	Fundamentals of Transport Processes	Prof. V. Kumaran	Video	IISc Bangalore	Select Introduction Dimensional Analysis Dimensional Analysis contd. Dimensionless Groups Continuum description Mechanisms of diffusion - I Mechanisms of diffusion - II Unidirectional Transport Cartesian Coordinates - I Unidirectional Transport Cartesian Coordinates - II Similarity Solutions Unidirectional Transport Cartesian Coordinates - III Similarity Solutions Unidirectional Transport Cartesian Coordinates - IV Seperation of Variables Unidirectional Transport Cartesian Coordinates - V Seperation of Variables Unidirectional Transport Cartesian Coordinates - VI Oscillatory Flows Unidirectional Transport Cartesian Coordinates - VII Momentum Source in the Flow Unidirectional Transport Cartesian Coordinates - VIII Heat & Mass Sources Unidirectional Transport Cylindrical Coordinates - I Conservation Equations Unidirectional Transport Cylindrical Coordinates - II Similarity Solutions Unidirectional Transport Cylindrical Coordinates - III Seperation of Variables Unidirectional Transport Cylindrical Coordinates - IV Steady flow in a pipe Unidirectional Transport Cylindrical Coordinates - V Oscillatory flow in a pipe Unidirectional Transport Cylindrical Coordinates - VI Oscillatory flow in a pipe Regular Perturbation Expansion Unidirectional Transport Cylindrical Coordinates - VII Oscillatory flow in a pipe Singular Perturbation Expansion Unidirectional Transport Spherical Coordinates - I Balance Equation Unidirectional Transport Spherical Coordinates - II Seperation of Variables Mass & Energy Conservation Cartesian Coordinates Mass & Energy Conservation Cartesian Coordinates Heat Conduction in a Cube Mass & Energy Conservation Spherical Coordinates Balance Laws Mass & Energy Conservation Cylindrical Coordinates Diffusion Equation Spherical Co-ordinates Seperation of Variables Diffusion Equation Spherical Co-ordinates Seperation of Variables contd. Diffusion Equation Spherical Co-ordinates Effective Conductivity of a Composite Diffusion Equation Spherical Harmonics Diffusion Equation Delta Functions Diffusion Equation Multipole Expansions Diffusion Equation Greens Function Formulations High Peclet Number Transport Flow Past a Flat Plate High Peclet Number Transport Heat Transfer from a Spherical Particle - I High Peclet Number Transport Heat Transfer from a Spherical Particle - II High Peclet Number Transport Heat Transfer from a Gas Bubble Summary
103108099	Chemical Engineering	Fundamentals of Transport Processes - II	Prof. V. Kumaran	Video	IISc Bangalore	Select 1.Review of Fundamentals of Transport Processors I 2.Introduction 3.Vectors and Tensors 4.Vector calculus 5.Vector calculus 6.Curvilinear co-ordinates 7.Kinematics 8.Rate of deformation tensor 9.Mass conservation equation 10.Momentum conservation equation 11.Angular momentum conservation equation 12.Boundary conditions 13.Mechanical energy conservation 14.Unidirectional flow 15.Viscous flows 16.Viscous flows 17.Flow around a sphere 18.Force on moving sphere 19.Torque on rotating sphere 20.Effective viscosity of a suspension 21.Flow in a corner 22.Lubrication flow 23.Lubrication flow 24.Inertia of a low Reynolds number 25.Potential flow 26.Potential flow around a sphere 27.Two-dimensional potential flow 28.Two-dimensional potential flow 29.Flow around a cylinder 30.Conformal transforms in potential flow 31.Boundary layer theory 32.Boundary layer past a flat plate 33.Stagnation point flow 34.Falkner-Skan Boundary Layer Solutions 35.Falkner-Skan Boundary Layer Solutions 36.Vorticity Dynamics 37.Vorticity Dynamics 38.Turbulence 39.Turbulence 40.Turbulent flow in a channel
103103039	Chemical Engineering	Process Design Decisions and Project Economics	Dr. Vijay S. Moholkar	Video	IIT Guwahati	Select General Introduction to the Course and Syllabus Hierarchical Approach to Process Design – I Hierarchical Approach to Process Design - Examples Input Information and Design Aspects of Batch vs. Continuous Process Input / Output Structure of Flowsheet (Part I) Input / Output Structure of Flowsheet (Part II) Input / Output Structure of Flowsheet (Part III) and Recycle Structure of Flowsheet (Part I) Recycle Structure of Flowsheet (Part II) Recycle Structure of Flowsheet (Part III) Recycle Structure of Flowsheet (Part IV) and Tutorial (Part I) Tutorial (Part II) Tutorial (Part III) Algorithm and Basic Principles of Reactor Design Reactor Non-ideality, Residence Time Distribution (RTD) and Types of Chemical Reactions & Catalysts Types of Reactors and Selection Criteria Tutorial on Reactor Design and Cost Estimation General Introduction (Types of Separation Processes and Criteria for Selection of the Processes) Guidelines for Design of Separation Systems Design of Distillation Columns – Part I (Sequencing of Columns, Energy Integration / Thermal Coupling of the Columns) Design of Distillation Columns – Part II (Plate and Packed Towers, Number of Plates, Diameter and Height of the Column) Tutorial – Part I (Design of Absorption Column) Tutorial – Part II (Design of Distillation Column) Concepts and Basic Principles of Energy (or Heat) Integration – Part 1 (Composite Curves and ?Tmin) Concepts and Basic Principles of Heat Integration – Part 2 (Problem Table Algorithm and Identification of Energy Targets) Identification of Area and Cost Targets Pinch Technology for Heat Exchanger Network Design Tutorial - I (Composite Curves, Problem Table Algorithm and Enthalpy Intervals) Tutorial - II (Heat Exchanger Network Synthesis Using Pinch Technology) Selection of Process, Design of Flowsheet and Materials Balance Energy Balance, Process Alternatives and Design of the Absorber Rules of Thumb & Their Limitations and Tutorial General Concepts & Principles and Cost Allocation Procedure Lumped Cost Diagram and Cost Allocation Diagram (Case Study of Hydro-dealkylation Process) Assessment of Process Alternatives with Cost Allocation Diagram (Case Study of Hydrodealkylation Process) Tutorial on Lumped Cost Diagram and Cost Allocation Diagram Introduction to Chemical Projects and Their Economic Aspects Selection of the Process and Project Site (Part I) Selection of the Process and Project Site (Part II) Project Cost Estimation (Part I) Project Cost Estimation (Part II) Simplified Cost Model and Depreciation Time Value of Money Measures of Profitability and Project Evaluation (Part I) Measures of Profitability and Project Evaluation (Part II) Tutorial on Project Economics (Part I) Tutorial on Project Economics (Part II)
103105065	Chemical Engineering	Instability & Patterning of Thin Polymer Films	Dr. R. Mukherjee	Web	IIT Kharagpur	Select Introduction to Patterned Surfaces and Their Applications Application of Patterned Surfaces: Structural Superhydrophobicity Application of Patterned Surfaces: Structural Color Fundamental Concepts Related Surface and Interfacial Tension Fundamental Concepts Related Surface and Interfacial Tension –2 Laplace Pressure and Young Laplace Equation Some Case studies with Young Laplace Equation for an Axi-Symmetric Surface Some Case studies with Young Laplace Equation for an Axi-Symmetric Surface (Continued) Meso Scale Patterning Approaches Meso Scale Patterning Approaches (Continued) Photolithography Photolithography – 2 (Continued) Photolithography – 3 (Continued) Photolithography – 4 (Continued) Photolithography – 5 (Continued) Nano Imprint Lithography – 1 Nano Imprint Lithography – 2 Soft Lithography – 1 Soft Lithography – 2 Soft Lithography – 3: Thin Polymer Blends – 1 Thin Polymer Blend films – 2 Intermolecular Force between Surfaces and Particles Spontaneous Instability and Dewetting of a Thin Polymer Film – 1 Spontaneous Instability and Dewetting of a Thin Polymer Film – 2 Spontaneous Instability and Dewetting of a Thin Polymer Film – 3 Spontaneous Instability and Dewetting of a Thin Polymer Film – 4 Spontaneous Instability and Dewetting of a Thin Polymer Film – 5 Spontaneous Instability and Dewetting of a Thin Polymer Film – 6 Pattern Directed Dewetting – 1 Pattern Directed Dewetting – 2 Dewetting of a Thin Polymer Bilayer Elastic Contact Instability Elastic Contact Lithography Elastic Recovery Lithography External Field Mediated Instability Evaporative Pattern formation (Coffee Stain Effect) Atomic Force Microscopy – 1 Atomic Force Microscopy – 2 Atomic Force Microscopy – 3: Additional Modes of AFM
103105110	Chemical Engineering	Fuel and Combustion Technology	Prof. Jayanta Kumar Basu, Prof. Sonali Sengupta	Web	IIT Kharagpur	Select History of Fuels History of liquid fuel and gaseous fuels Production, present scenario and consumption pattern of fuels Definitions and properties of solid fuels Fundamental definiti ons, properties and various measurements Fundamental definiti ons, properties and various measurements Coal classifica tion, composition and basis Coal Mining Coal preparation and washing Combustion of coal and coke making Different types of coal combustion techniques Combustion of coal and coke making Coal liquefaction Coal Li quefaction (Contd.) Coal Gasification Exploration of crude petroleum Evaluation of crude Distillation Vacuum Distillation Secondary Processing Secondary Processing Secondary Processing (Contd.) Secondary Processing (Contd.) Hydrotreatment, dewaxing, deasphalting Refinery Equipments Gaseous Fuel Producer Gas Water Gas Hydrogen gas Acetylene Other fuel gases Fundamentals of thermochemistry Combustion air calculation Calculation of calorific value of fuels Adiabatic flam e temperature calculation Mechanism and kinetics of combustion Flame Properties Combustion Burners Combustion Furnaces Internal Combustion Engine
103107081	Chemical Engineering	Chemical Technology - I	Dr. I.D.Mall	Video	IIT Roorkee	Select Introduction to Chemical process Industries Raw material for Organic Chemical Industries Unit processes and unit operations in organic chemical Industries Coal and coal as chemicals feed stock Coal carbonization and Coke oven plant Gasification of Coal,Petrocoke and Biomass Introduction to Pulp and paper Industry, Raw material for paper industry and Technological development Pulping and Bleaching Recovery of Chemicals Stock preparation and paper making Introduction to Soap and detergent, Soap making and Recovery of Glycerine Synthetic detergent and Linear alkyl benzene Sugar and Fermentation industry Ethanol as Biofuel and Chemical feed stock Introduction : Staus of Petroleum refinery, Crude oil and Natural gas origin, occurrence, exploration, drilling and processing, Fuel norms Evaluation of Crude oil,Petroleum Products and Apetrochemicals Crude oil Distillation Thermal Cracking: Visbreaking and Delayed Coking Catalytic cracking: Fluid Catalytic cracking and Hydro cracking Catalytic reforming Alkylation, Isomerisation and Polymerisation Desulphurisation Processes and Recovery of Sulphur Profile of petrochemical Industry and its structure Naphtha and gas cracking for production of olefins Recovery of chemicals from FCC and steam cracking Synthesis gas and its derivatives: Hydrogen, CO, Methanol, Formaldehyde Ethylene derivatives: Ethylene Oxide, Ethylene glycol, Ethylene dichloride and Vinyl chloride Propylene, Propylene oxide and Isopropanol Aromatics Production Aromatics product profile, Ethyl benzene &Styrene, Cumene and phenol, Bisphenol, Aniline Introduction to polymer, Elastomer and Synthetic Fibre, Polymerisation Polymers:Polyolefins,Polyethylene,Polypropylene Polystyrene Polyvinylchloride,polycarbonate,thermoset resin: phenolformaldehyde,uriaformaldehyde and melamineformaldehyde Elastomers: Styrene butadiene Rubber(SBR), Poly butadiene, Nitrile rubber Polymides or Nylons(PA) DMT and Terephtalic Acid,Polyester,PET resin,PTB resin Acrylic Fibre,Modified Acrylic Fibre,Acrylonitrile,Acrolein,Propylene Finber,Polyurethane Viscose Rayon and Acetate rayon Pesticide Dye and Intermediates
103108100	Chemical Engineering	Modern Instrumental Methods of Analysis	Dr. J.R. Mudakavi	Video	IISc Bangalore	Select Introduction to the Modern Instrumental Methods of Analysis Atomic Structure Physical Properties of Electromagnetic Radiation Interaction of Matter with Radiation Ultraviolet and Visible Spectrophotometry -1 i. Theoretical Aspects Ultraviolet and Visible Spectrophotometry -2 ii. Theoretical Aspects Ultraviolet and Visible Spectrophotometry -3 iii. Theoretical Aspects Ultraviolet and Visible Spectrophotometry -4 iv. Instrumentation Ultraviolet and Visible Spectrophotometry -5 v. Instrumentation Ultraviolet and Visible Spectrophotometry -6 vi. Applications Fluorescence and Phosphorescence Spectrophotometry 1 i. Theoretical Aspects Fluorescence and Phosphorescence Spectrophotometry -2 ii. Instrumentation Fluorescence and Phosphorescence Spectrophotometry -3 iii. Application Atomic Fluorescence i. Theoretical aspects X- Ray Analytical Techniques -1 ii. Instrumentation X- Ray Analytical Techniques -2 iii. Applications Atomic Absorption Spectrometry -1 i. Theoretical Aspects Atomic Absorption Spectrometry -2 ii.Theoretical Aspects Atomic Absorption Spectrometry -3 iii. Instrumentation Atomic Absorption Spectrometry -4 iv. Instrumentation Atomic Absorption Spectrometry -5 v. Instrumentation Atomic Absorption Spectrometry -6 vi. Signal handling Atomic Absorption Spectrometry -7 vii. Interferences Atomic Absorption Spectrometry -8 viii. Hydride Generation AAS Atomic Absorption Spectrometry -9 ix.Cold Vapour Mercury AAS Electrothermal Atomic Absorption Spectrometry -10 x. Electrothermal Aspects Electrothermal Atomic Absorption Spectrometry -11 xi. Practical Aspects Inductively Coupled Plasma Atomic Emission Spectrometry -1 i. Theoretical Aspects Inductively Coupled Plasma Atomic Emission Spectrometry -2 ii. Instrumentation Inductively Coupled Plasma Atomic Emission Spectrometry -3 iii. Comparison of ICP & AAS Infrared Spectroscopy -1 i. Theoretical Aspects Infrared Spectroscopy -2 ii. Practical Aspects Infrared Spectroscopy -3 iii. Nondispensive IR, Mass spectrometer Introduction to Mass Spectrometry Introduction to Nuclear Magnetic Resonance Spectroscopy Fundamentals of Electrochemical Techniques -1 i. Introduction Fundamentals of Electrochemical Techniques -2 ii. Introduction continued Polarography -1 i. Introduction Polarography -2 ii. Applications Chromatography -1 i. Introduction Gas chromatography -1 i. Instrumentation Gas chromatography -2 ii. Applications Gas chromatography -3 iii. Applications
103106112	Chemical Engineering	Statistics for Experimentalists	Dr. A. Kannan	Video	IIT Madras	Select Introduction Random Variables Discrete Probability Distributions Example Set - I Continuous probability distributions Normal probability distribution Exploratory Data Analysis – Part A Exploratory Data Analysis – Part B Example Set II Example Set III Random samples: Sampling distribution of the mean (Part A) Random samples: Sampling distribution of the mean (Part B) Point Estimation Sampling distributions and the Central Limit Theorem Example Set – IV Part A Estimation of Population Parameters Using Moments Confidence Intervals (Part A) Confidence Intervals (Part B) The T-distribution Chi-square distribution F-Distribution Example Set 5 Hypothesis Testing – Part A Hypothesis Testing – Part B Hypothesis Testing – Part C Analysis of Experiments involving Single Factor – Part A Analysis of Experiments involving Single Factor – Part B Blocking and Randomization Example Set -6 – Part A Example Set -6 – Part B Factorial Design of Experiments – Part A Factorial Design of Experiments – Part B: 22 Factorial Design Fractional Factorial Design – Part A Fractional Factorial Design – Part B Factorial Design of Experiments: Example Set (Part A) Factorial Design of Experiments: Example Set (Part B) Factorial Design of Experiments: Example Set (Part C) Regression Analysis: Part A Regression Analysis: Part B Hypothesis Testing in Linear Regression Discussion on Regression Output Regression Analysis : Example Set 8 Regression Analysis: Example Set 8 Continued Regression Analysis: Example Set 8 Continued. Orthogonal Model Fitting Concepts - Part A Orthogonal Model Fitting Concepts – Part B Experimental Design Strategies - A Experimental Design Strategies - B Experimental Design Strategies - C Response Surface Methodology - A Response Surface Methodology - B Optimal Designs – Part A Optimal Designs – Part B Statistics for Experimentalists – Summary Part A Statistics for Experimentalists – Summary Part B