DIGIMAT LEARNING MANAGEMENT PLATFORM

Chemistry and Biochemistry (5,133 Video Lectures)

Link NPTEL Course Name NPTEL Lecture Title
Link NOC:Organo Metallic Chemistry Lecture 1 - Introduction of Organometallic Chemistry
Link NOC:Organo Metallic Chemistry Lecture 2 - Counting of Electrons
Link NOC:Organo Metallic Chemistry Lecture 3 - Ligand Substitution Reactions
Link NOC:Organo Metallic Chemistry Lecture 4 - Oxidative Addition [1.Concerted Mechanism]
Link NOC:Organo Metallic Chemistry Lecture 5 - Oxidative Addition [2.SN2 Mechanism]
Link NOC:Organo Metallic Chemistry Lecture 6 - Oxidative Addition [3. Radical Mechanism]
Link NOC:Organo Metallic Chemistry Lecture 7 - Reductive Elimination
Link NOC:Organo Metallic Chemistry Lecture 8 - Migratory Insertion and Elimination Reactions
Link NOC:Organo Metallic Chemistry Lecture 9 - Migration and Insertion Reactions
Link NOC:Organo Metallic Chemistry Lecture 10 - Alpha-Migratory Insertion and alpha-Elimination Reactions
Link NOC:Organo Metallic Chemistry Lecture 11 - Beta-Migratory Insertion
Link NOC:Organo Metallic Chemistry Lecture 12 - Beta-Elimination Reaction
Link NOC:Organo Metallic Chemistry Lecture 13 - Alpha-Abstraction and beta-Abstraction
Link NOC:Organo Metallic Chemistry Lecture 14 - 4-Center Reactions; [2+2] Reactions
Link NOC:Organo Metallic Chemistry Lecture 15 - External Attack by a Ligand and Reductive Coupling
Link NOC:Organo Metallic Chemistry Lecture 16 - Hydrogenation Reaction
Link NOC:Organo Metallic Chemistry Lecture 17 - Hydrogenation Reaction [Dihydride Catalyst]
Link NOC:Organo Metallic Chemistry Lecture 18 - Stereoselective Hydrogenation Reaction
Link NOC:Organo Metallic Chemistry Lecture 19 - Carbonylation Reaction [1. Monsanto Acetic Acid Process 2. Hydroformylation 3. Hydrocarboxylation]
Link NOC:Organo Metallic Chemistry Lecture 20 - Carbonylation Reaction [1. Hydroformylation 2. Hydrocarboxylation 3. Hydrocyanation]
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 1 - Fundamentals of Chemical thermodynamics
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 2 - Work
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 3 - Tutorial-1
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 4 - First Law of Thermodynamics
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 5 - Tutorial-2
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 6 - Adiabatic processes
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 7 - Entropy
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 8 - Entropy and Second Law: Basics
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 9 - Entropy and Second Law: Applications
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 10 - Third Law of Thermodynamics
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 11 - Discussion on Helmholtz energy
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 12 - Discussion on Gibbs Energy
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 13 - Maxwell relations, Properties of Gibbs energy
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 14 - Further discussion on properties of Gibbs energy
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 15 - Fugacity
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 16 - Tutorial session
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 17 - Tutorial session
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 18 - Chemical potential of a substance in mixture
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 19 - Chemical potential of Liquids, Raoult’s Law, Henry’s Law
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 20 - Thermodynamics of mixing, Excess functions
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 21 - Partial molar volume
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 22 - Activities (Accounting for deviations from Ideal behaviour)
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 23 - Tutorial on thermodynamics of mixing and deviations from ideality
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 24 - Further discussion on relation between C p and C v
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 25 - Chemical Equilibrium
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 26 - Perfect gas equilibria
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 27 - Equilibrium constant
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 28 - Effect of pressure on equilibrium constant and equilibrium composition
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 29 - Effect of temperature on equilibria
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 30 - Biological standard states and pH
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 31 - Tutorial 1 - Equilibrium constant
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 32 - Tutorial 2 - Equilibrium constant
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 33 - Acids and bases and Equilibrium concepts
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 34 - pH Scale Strong and weak acids and bases
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 35 - Strong and weak acids and bases
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 36 - Acid-base titrations
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 37 - pH curve for titration of weak acid with strong base Buffers and indicators
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 38 - Thermodynamics in systems of biological interest
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 39 - Calorimetry
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 40 - Differential scanning calorimetry (DSC)
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 41 - Further discussion on Differential Scanning Calorimetry (DSC)
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 42 - Explaining Differential Scanning Calorimetric Profiles (DSC Profiles)
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 43 - Applications of DSC in thermal unfolding of proteins and protein-solvent interactions
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 44 - Further discussion on applications of DSC in thermal unfolding of proteins and protein-solvent interactions
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 45 - Isothermal Titration calorimetry (ITC)
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 46 - Further discussion on Isothermal Titration calorimetry (ITC)
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 47 - ITC Experimental Design and Isothermal Titration Calorimetry (ITC) in Drug Design
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 48 - Isothermal Titration Calorimetry (ITC) in Drug Design
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 49 - Isothermal Titration Calorimetry (ITC) in Engineering Binding Affinity
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 50 - Calorimetry in identifying partially folded states of proteins (Molten Globule State)
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 51 - Thermodynamic Characterization of Partially Folded States of Proteins
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 52 - Quantitative Thermodynamic Characterization of Partially Folded States of Proteins
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 53 - ITC in Drug-Protein Interactions
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 54 - Identifying sites for Drug-Protein Interactions by ITC
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 55 - Identifying sites for Drug-Protein Interactions, DSC of Protein-Ligand Complexes. Enthalpy-Entropy Compensation
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 56 - Estimation of Binding Constants in Strong to Ultratight Protein-Ligand, Interactions Using Differential Scanning Calorimetry
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 57 - Continuation of discussion on... Estimation of Binding Constants in Strong to UltratightProtein-Ligand Interactions Using Differential Scanning Calorimetry
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 58 - Thermal unfolding of protein by non-calorimetric methods, Addressing thermodynamics of the process
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 59 - Titration Calorimetry as a tool to determine thermodynamic and Kinetic parameters of enzymes
Link NOC:Chemical and Biological Thermodynamics - Principles to Applications Lecture 60 - Summary of the course
Link NOC:Chemistry of Main Group Elements Lecture 1 - Classification of Elements and Periodic Properties
Link NOC:Chemistry of Main Group Elements Lecture 2 - Periodic Properties, Periodic Trends and Classification of Main Group Compounds
Link NOC:Chemistry of Main Group Elements Lecture 3 - Classification of Main Group Compounds
Link NOC:Chemistry of Main Group Elements Lecture 4 - Effective Nuclear Charge
Link NOC:Chemistry of Main Group Elements Lecture 5 - Structure and Bonding Aspects: Lewis Structures and VSEPR Theory
Link NOC:Chemistry of Main Group Elements Lecture 6 - Structure and Bonding Aspects: VSEPR Theory
Link NOC:Chemistry of Main Group Elements Lecture 7 - Structure and Bonding Aspects: Valence Bond Theory
Link NOC:Chemistry of Main Group Elements Lecture 8 - Structure and Bonding Aspects: Valence Bond Theory
Link NOC:Chemistry of Main Group Elements Lecture 9 - Structure and Bonding Aspects: MO Theory
Link NOC:Chemistry of Main Group Elements Lecture 10 - Structure and Bonding Aspects: MO Theory
Link NOC:Chemistry of Main Group Elements Lecture 11 - Structure and Bonding Aspects: MO Theory
Link NOC:Chemistry of Main Group Elements Lecture 12 - Structure and Bonding Aspects: MO Theory
Link NOC:Chemistry of Main Group Elements Lecture 13 - Chemistry of Hydrogen
Link NOC:Chemistry of Main Group Elements Lecture 14 - Chemistry of Hydrogen
Link NOC:Chemistry of Main Group Elements Lecture 15 - Chemistry of Hydrogen, Hydrides and Hydrogen Bonding
Link NOC:Chemistry of Main Group Elements Lecture 16 - Chemistry of Group 1 Elements
Link NOC:Chemistry of Main Group Elements Lecture 17 - Chemistry of Group 1 Elements
Link NOC:Chemistry of Main Group Elements Lecture 18 - Chemistry of Group 1 Elements
Link NOC:Chemistry of Main Group Elements Lecture 19 - Chemistry of Group 1 Elements
Link NOC:Chemistry of Main Group Elements Lecture 20 - Chemistry of Group 2 Elements
Link NOC:Chemistry of Main Group Elements Lecture 21 - Chemistry of Group 2 Elements
Link NOC:Chemistry of Main Group Elements Lecture 22 - Chemistry of Group 2 Elements
Link NOC:Chemistry of Main Group Elements Lecture 23 - Chemistry of Group 2 Elements
Link NOC:Chemistry of Main Group Elements Lecture 24 - Chemistry of Group 2 Elements
Link NOC:Chemistry of Main Group Elements Lecture 25 - Chemistry of Group 13 Elements
Link NOC:Chemistry of Main Group Elements Lecture 26 - Chemistry of Group 13 Elements
Link NOC:Chemistry of Main Group Elements Lecture 27 - Chemistry of Group 13 Elements
Link NOC:Chemistry of Main Group Elements Lecture 28 - Chemistry of Group 13 Elements
Link NOC:Chemistry of Main Group Elements Lecture 29 - Chemistry of Group 13 Elements
Link NOC:Chemistry of Main Group Elements Lecture 30 - Wades Rules
Link NOC:Chemistry of Main Group Elements Lecture 31 - Chemistry of Group 13 Elements
Link NOC:Chemistry of Main Group Elements Lecture 32 - Chemistry of Group 14 Elements
Link NOC:Chemistry of Main Group Elements Lecture 33 - Chemistry of Group 14 Elements
Link NOC:Chemistry of Main Group Elements Lecture 34 - Chemistry of Group 14 Elements
Link NOC:Chemistry of Main Group Elements Lecture 35 - Chemistry of Group 14 Elements
Link NOC:Chemistry of Main Group Elements Lecture 36 - Chemistry of Group 14 Elements
Link NOC:Chemistry of Main Group Elements Lecture 37 - Chemistry of Group 14 Elements
Link NOC:Chemistry of Main Group Elements Lecture 38 - Chemistry of Group 14 Elements
Link NOC:Chemistry of Main Group Elements Lecture 39 - Chemistry of Group 15 Elements
Link NOC:Chemistry of Main Group Elements Lecture 40 - Chemistry of Group 15 Elements
Link NOC:Chemistry of Main Group Elements Lecture 41 - Chemistry of Group 15 Elements
Link NOC:Chemistry of Main Group Elements Lecture 42 - Chemistry of Group 15 Elements
Link NOC:Chemistry of Main Group Elements Lecture 43 - Chemistry of Group 15 Elements
Link NOC:Chemistry of Main Group Elements Lecture 44 - Chemistry of Group 15 Elements
Link NOC:Chemistry of Main Group Elements Lecture 45 - Chemistry of Group 15 Elements
Link NOC:Chemistry of Main Group Elements Lecture 46 - Chemistry of Group 15 Elements
Link NOC:Chemistry of Main Group Elements Lecture 47 - Chemistry of Group 16 Elements
Link NOC:Chemistry of Main Group Elements Lecture 48 - Chemistry of Group 16 Elements
Link NOC:Chemistry of Main Group Elements Lecture 49 - Chemistry of Group 16 Elements
Link NOC:Chemistry of Main Group Elements Lecture 50 - Chemistry of Group 16 Elements
Link NOC:Chemistry of Main Group Elements Lecture 51 - Chemistry of Group 16 Elements
Link NOC:Chemistry of Main Group Elements Lecture 52 - Chemistry of Group 17 Elements
Link NOC:Chemistry of Main Group Elements Lecture 53 - Chemistry of Group 17 Elements
Link NOC:Chemistry of Main Group Elements Lecture 54 - Chemistry of Group 18 Elements
Link NOC:Chemistry of Main Group Elements Lecture 55 - Chemistry of Group 12 Elements
Link NOC:Chemistry of Main Group Elements Lecture 56 - Organometallic Compounds of Main Group Elements
Link NOC:Chemistry of Main Group Elements Lecture 57 - Organometallic Compounds of Main Group Elements
Link NOC:Chemistry of Main Group Elements Lecture 58 - Organometallic Compounds of Main Group Elements
Link NOC:Chemistry of Main Group Elements Lecture 59 - Organometallic Compounds of Main Group Elements
Link NOC:Chemistry of Main Group Elements Lecture 60 - Overall Summary
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 1 - History of Organometallic Compounds
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 2 - Polarity and Reactivity of M−C bonds
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 3 - Reactivity of Organometallic Compounds
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 4 - Reactivity of Organometallic Compounds
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 5 - 18 Valence Electron Rule and Classification
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 6 - 18 Valence Electron Rule and Classification
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 7 - Reactivity and types of Organometallic compounds
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 8 - Sigma-Donor Ligands
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 9 - Preparation of Sigma-Alkyl Compounds
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 10 - Preparation and Properties of Sigma-Alkyl Compounds
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 11 - Properties of Sigma-Alkyl Compounds
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 12 - β−elimination in Sigma-Alkyl Compounds
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 13 - β−elimination in Detail
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 14 - TM Sigma-Alkyl Complexes and its Application
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 15 - TM Sigma-Alkyl Complexes and its Application
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 16 - C−H Activation
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 17 - C−H Activation in Details
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 18 - C−H Activation in Details
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 19 - Characterization of C−H Activation
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 20 - Bonding in C−H Activation
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 21 - C−C Bond Activation
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 22 - C−C Bond Activation
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 23 - C−C Bond Activation in Details
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 24 - Transition Metal Perfluoroalkyl (RF−TM) Complexes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 25 - Preparation of Transition Metal Perfluoroalkyl (RF−TM) Complexes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 26 - C−F Activation
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 27 - Transition Metal Alkenyl/Aryl Complexes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 28 - Transition Metal Aryl Complexes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 29 - Transition Metal Aryl/Alkyne Complexes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 30 - Transition Metal Alkyne/Carbene Complexes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 31 - Transition Metal Carbene Complexes: Preparations
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 32 - Transition Metal Carbene Complexes: Properties
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 33 - Transition Metal Carbene Complexes: Reactivities
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 34 - Transition Metal Carbene Complexes: Reactivities
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 35 - Transition Metal Carbene Complexes: Reactivities
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 36 - Transition Metal Carbene Complexes: Reactivities
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 37 - Reactivity of Schrock type Carbene Complexes and Transition Metal Carbynes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 38 - Transition Metal Carbynes: Preparation
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 39 - Transition Metal Carbynes: Properties
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 40 - Transition Metal Carbynes: Properties
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 41 - Properties of Transition Metal Carbynes And Transition Metal Carbonyls
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 42 - Transition Metal Carbonyls
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 43 - Transition Metal Carbonyls
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 44 - Transition Metal Carbonyls: Bonding Properties
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 45 - Transition Metal Carbonyls: Bonding properties
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 46 - Transition Metal Carbonyls: Reactivities
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 47 - Transition Metal Carbonyls: Reactivity and Carbonyl Metallates
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 48 - Transition Metal Carbonyl Hydrides
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 49 - Application of Carbonyl Metallates and Metal Halides
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 50 - Application of Metal Halides and Metal Alkenes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 51 - Transition Metal Olefin Complexes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 52 - Transition Metal Olefin Complexes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 53 - Transition Metal Olefin Complexes: Reactivity
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 54 - Bonding Properties in Olefin Complexes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 55 - Transition Metal Diolefin Complexes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 56 - Transition Metal Diolefin and Alkyne Complexes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 57 - Transition Metal Alkyne Complexes
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 58 - Transition Metal Alkyne Complexes: Reactivity
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 59 - Transition Metal Alkyne Complexes: Reactivity
Link NOC:Transition Metal Organometallic Chemistry - Principles to Applications Lecture 60 - Summary: Transition Metal Organometallic Chemistry: Principles to Applications
Link NOC:Metal Mediated Synthesis-I Lecture 1 - Assymetric Hydrogenation
Link NOC:Metal Mediated Synthesis-I Lecture 2 - Transition Metal Carbenes Fischerand Schrock Carbenes
Link NOC:Metal Mediated Synthesis-I Lecture 3 - Olefin Metathesis
Link NOC:Metal Mediated Synthesis-I Lecture 4 - Alkyne Metathesis
Link NOC:Metal Mediated Synthesis-I Lecture 5 - Cyclopropanation Reaction
Link NOC:Metal Mediated Synthesis-I Lecture 6 - Catalytic Cyclopropanation Reaction and Introduction to Cross Coupling Reaction
Link NOC:Metal Mediated Synthesis-I Lecture 7 - Kumada Coupling Reaction
Link NOC:Metal Mediated Synthesis-I Lecture 8 - Suzuki Coupling Reaction
Link NOC:Metal Mediated Synthesis-I Lecture 9 - Stille Coupling Reaction
Link NOC:Metal Mediated Synthesis-I Lecture 10 - Assymetric Suzuki Coupling Reaction
Link NOC:Metal Mediated Synthesis-I Lecture 11 - Sonogashira Coupling Reaction
Link NOC:Metal Mediated Synthesis-I Lecture 12 - Heck Coupling Reaction
Link NOC:Metal Mediated Synthesis-I Lecture 13 - Assymetric Heck Reaction Introduction to Buchwald-Hartwig Coupling Reaction
Link NOC:Metal Mediated Synthesis-I Lecture 14 - Buchwald-Hartwig Coupling Reaction
Link NOC:Metal Mediated Synthesis-I Lecture 15 - Role of Ligands its Influence in Buchwald-Hartwig Coupling Reaction
Link NOC:Metal Mediated Synthesis-I Lecture 16 - Oxidative Cyclization Process
Link NOC:Metal Mediated Synthesis-I Lecture 17 - Application of Oxidative Cyclization in Natural Product Synthesis
Link NOC:Metal Mediated Synthesis-I Lecture 18 - Synthesis of Reactive Metallacycle Intermediate Via-Beta-Abstraction and their Applications
Link NOC:Metal Mediated Synthesis-I Lecture 19 - Kulinkovich Reaction and its Mechanism
Link NOC:Metal Mediated Synthesis-I Lecture 20 - Pauson–Khand Reaction
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 1 - Overview of inorganic chemistry of life
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 2 - Elements in biology and or life
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 3 - Selection and criteria for elements
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 4 - Biomolecules
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 5 - Coordination in enzymes
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 6 - Amino acids, peptides and proteins - An introduction
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 7 - Nucleoside, nucleotide and nucleic acids and DNA: An introduction
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 8 - General introduction of metalloproteins
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 9 - Coordination chemistry aspects - An introduction
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 10 - Stability and lability
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 11 - Techniques used inorganic chemistry life
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 12 - Techniques used inorganic chemistry life (Continued...)
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 13 - Techniques used inorganic chemistry life (Continued...)
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 14 - Techniques used inorganic chemistry life (Continued...)
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 15 - Recap on metalloenzymes
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 16 - Role of Alkali, Alkaline earth elements in life
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 17 - Role of Alkali, Alkaline earth elements in life (Continued...)
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 18 - Role of Alkali, Alkaline earth elements in life (Continued...) Ion transport and ionophores
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 19 - Role of Alkali, Alkaline earth elements in life (Continued...) Ion transport and ionophores
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 20 - Functioning of ATPases and nucleases [Na,K]ATPase
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 21 - Role of vanadium in life - General perspectives
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 22 - Role of vanadium in life - Haloperoxidases
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 23 - Enzymes based on manganese in life
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 24 - Role of Iron in life - General perspectives
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 25 - Role of Iron in life - Transport systems
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 26 - Role of Iron in life - Transport and Storage systems
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 27 - Role of Iron in life - Electron transfer
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 28 - Role of Iron in life - Perspectives of electron transfer proteins
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 29 - Role of Iron in life - Monooxygenases: Cytochrome P450
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 30 - Role of Iron in life - Mono-and di-oxygenases
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 31 - Role of Iron in life - Reductases
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 32 - Role of Iron in life - Reductases and Phosphatases
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 33 - Role of Iron in life - Reductases and Phosphatases (Continued...)
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 34 - Role of Cobalt in life
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 35 - Role of Nickel in life - General perspectives
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 36 - Role of Nickel in life - Hydrolase, hydrogenase and SOD
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 37 - Role of Nickel in life - Carbonmonoxide dehydrogenase (CODH)
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 38 - Role of Copper in life - General perspectives
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 39 - Role of Copper in life - Type I and Type 2 copper enzymes
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 40 - Role of Copper in life - Multicenter copper oxidases and SOD
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 41 - Role of Zinc in life - General perspectives including oxidoreductases and hydrolases
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 42 - Role of Zinc in life - Carbonic anhydrase and carboxypeptidase
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 43 - Role of Zinc in life - Transferases, ligages and isomerases
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 44 - Role of Molybdenum in life - Introductory aspects
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 45 - Role of Molybdenum in life - Nitrogenase
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 46 - Role of Molybdenum in life - Oxidoreductases
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 47 - Role of Mercury in the environment - Mercury reductase
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 48 - Role of Selenium in life - Glutathione perioxidase
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 49 - Inorganics in medicine - Introductory aspects and cis-platin
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 50 - Inorganics in medicine - Apoptosis
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 51 - Inorganics in medicine - PDT, MRI and Barium tests
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 52 - Inorganics in medicine - Titanium in biomedical
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 53 - Highlights of the course - Part I
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 54 - Highlights of the course - Part II
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 55 - Highlights of the course - Part III
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 56 - Highlights of the course - Part IV
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 57 - Tutorials - Part I
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 58 - Tutorials - Part II
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 59 - Tutorials - Part III
Link NOC:Inorganic Chemistry of Life: Principles and Perspectives Lecture 60 - Tutorials - Part IV and overall
Link NOC:Symmetry and Group Theory Lecture 1 - Symmetry point group: Introduction
Link NOC:Symmetry and Group Theory Lecture 2 - Symmetry point group: Examples - Part I
Link NOC:Symmetry and Group Theory Lecture 3 - Symmetry point group: Examples - Part II
Link NOC:Symmetry and Group Theory Lecture 4 - Symmetry point group: Examples - Part III
Link NOC:Symmetry and Group Theory Lecture 5 - Symmetry point group: Examples - Part IV
Link NOC:Symmetry and Group Theory Lecture 6 - Transformation matrices and Matrix representation
Link NOC:Symmetry and Group Theory Lecture 7 - More on Matrix representation: Cartesian coordinates in C2v point group
Link NOC:Symmetry and Group Theory Lecture 8 - Matrix representation: the way ahead
Link NOC:Symmetry and Group Theory Lecture 9 - Introduction to Group Theory
Link NOC:Symmetry and Group Theory Lecture 10 - Group Multiplication Tables
Link NOC:Symmetry and Group Theory Lecture 11 - Groups and subgroups
Link NOC:Symmetry and Group Theory Lecture 12 - Classes, Similarity transformations
Link NOC:Symmetry and Group Theory Lecture 13 - Introduction to Matrices
Link NOC:Symmetry and Group Theory Lecture 14 - Application of matrices in solution of simultaneous equations
Link NOC:Symmetry and Group Theory Lecture 15 - Matrix eigenvalue equation
Link NOC:Symmetry and Group Theory Lecture 16 - Matrix eigenvalue equation: an example
Link NOC:Symmetry and Group Theory Lecture 17 - Similarity Transformations
Link NOC:Symmetry and Group Theory Lecture 18 - Back to transformation matrices
Link NOC:Symmetry and Group Theory Lecture 19 - Matrix representation revisited
Link NOC:Symmetry and Group Theory Lecture 20 - Function space and Transformation Operators
Link NOC:Symmetry and Group Theory Lecture 21 - Transformation Operators form the same group as transformation matrices
Link NOC:Symmetry and Group Theory Lecture 22 - Transformation Operators form a unitary representation for orthonormal basis
Link NOC:Symmetry and Group Theory Lecture 23 - Transformation Operators: Switching Bases
Link NOC:Symmetry and Group Theory Lecture 24 - Equivalent representations
Link NOC:Symmetry and Group Theory Lecture 25 - Unitary Transformation
Link NOC:Symmetry and Group Theory Lecture 26 - Unitary Transformations (Continued...)
Link NOC:Symmetry and Group Theory Lecture 27 - Reducible and Irreducible Representations
Link NOC:Symmetry and Group Theory Lecture 28 - Irreducible Representations and Great Orthogonality Theorem
Link NOC:Symmetry and Group Theory Lecture 29 - Character Tables: C2v
Link NOC:Symmetry and Group Theory Lecture 30 - Character Tables: C2v and C3v
Link NOC:Symmetry and Group Theory Lecture 31 - Practice Session: Review of Some Questions and Solutions
Link NOC:Symmetry and Group Theory Lecture 32 - Reducible to Irreducible Representations
Link NOC:Symmetry and Group Theory Lecture 33 - Character Tables of Cyclic Groups
Link NOC:Symmetry and Group Theory Lecture 34 - Symmetry of Normal Modes: D3h
Link NOC:Symmetry and Group Theory Lecture 35 - Symmetry of Normal Modes: D3h (Continued...)
Link NOC:Symmetry and Group Theory Lecture 36 - Symmetry of Normal Modes: a shortcut
Link NOC:Symmetry and Group Theory Lecture 37 - Recap: Reducible Representation for Normal Modes
Link NOC:Symmetry and Group Theory Lecture 38 - Contribution of internal motion to normal modes
Link NOC:Symmetry and Group Theory Lecture 39 - Normal mode analysis: some examples
Link NOC:Symmetry and Group Theory Lecture 40 - Infrared and Raman spectroscopy
Link NOC:Symmetry and Group Theory Lecture 41 - IR and Raman activity
Link NOC:Symmetry and Group Theory Lecture 42 - IR and Raman activity: examples
Link NOC:Symmetry and Group Theory Lecture 43 - Symmetry Adapted Linear Combinations (SALC)
Link NOC:Symmetry and Group Theory Lecture 44 - SALC:BeH2
Link NOC:Symmetry and Group Theory Lecture 45 - SALC:CH4 Introduction
Link NOC:Symmetry and Group Theory Lecture 46 - SALC:CH4
Link NOC:Symmetry and Group Theory Lecture 47 - Projection Operators
Link NOC:Symmetry and Group Theory Lecture 48 - Projection Operators (Continued...)
Link NOC:Symmetry and Group Theory Lecture 49 - Generating SALC’s using Projection Operators
Link NOC:Symmetry and Group Theory Lecture 50 - Generating SALC’s using Projection Operators (Continued...)
Link NOC:Symmetry and Group Theory Lecture 51 - Oh complex and Group-subgroup relation
Link NOC:Symmetry and Group Theory Lecture 52 - Group-Subgroup Relation
Link NOC:Symmetry and Group Theory Lecture 53 - SALCs as Pi-MO andCyclopropenyl group
Link NOC:Symmetry and Group Theory Lecture 54 - SALCs as Pi-MO, Cyclopropenyl group
Link NOC:Symmetry and Group Theory Lecture 55 - SALCs as Pi-MO, Benzene
Link NOC:Symmetry and Group Theory Lecture 56 - LCAO Huckel approximation
Link NOC:Symmetry and Group Theory Lecture 57 - Huckel approximation: Naphthalene
Link NOC:Symmetry and Group Theory Lecture 58 - Stationary states, Multiplicity, Ethylene
Link NOC:Symmetry and Group Theory Lecture 59 - Napthalene - I
Link NOC:Symmetry and Group Theory Lecture 60 - Napthalene - II
Link NOC:Symmetry and Group Theory Lecture 61 - Napthalene - III
Link NOC:Symmetry and Group Theory Lecture 62 - Transition Metal Complexes: CFT and LFT
Link NOC:Symmetry and Group Theory Lecture 63 - Jahn-Teller Theorem, Tetragonal Distortion MOT:ML6, Sigma and Pi Bonds
Link NOC:Symmetry and Group Theory Lecture 64 - MOT approach of bonding,H2O,Ferrocene
Link NOC:Symmetry and Group Theory Lecture 65 - MOT approach of bonding,H2O,Ferrocene
Link NOC:Symmetry and Group Theory Lecture 66 - Derivation: Great Orthogonality Theorem - I (Schurrs Lemma 1)
Link NOC:Symmetry and Group Theory Lecture 67 - Derivation: Great Orthogonality Theorem - II (Schurrs Lemma 2)
Link NOC:Symmetry and Group Theory Lecture 68 - Derivation: Great Orthogonality Theorem - III
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 1 - Introduction to Computational Chemistry
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 2 - Writing Simple Programs: Compilation and Execution
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 3 - Programming Techniques 1 - Evaluating the sine function
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 4 - Programming Techniques 2 - Do loops and if statements
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 5 - Programming Techniques 3 - Roots of a quadratic equation and arrays
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 6 - Programming Techniques 4 - Arrays and matrices
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 7 - Practical Session of Programming 1
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 8 - Programming Techniques 5 - Formats, Functions and Subroutines
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 9 - Programming Techniques 6 - Functions and Subroutines, arranging numbers in as ascending order
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 10 - Programming Techniques 7 - Functions and Subroutines, and the common statement
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 11 - Numerical Methods. Analysis of errors
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 12 - Practical Session on Programming 2 - The exponential function
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 13 - Practical Session on Programming 3 - Functions and Subroutines
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 14 - Interpolation Methods-1
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 15 - Interpolation Methods-2: Newton’s and Lagrange Interpolation
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 16 - Errors in interpolation, Matrix operations
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 17 - Gauss elimination method for matrix inversion
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 18 - Matrix diagonalization, Similarity transformations
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 19 - Matrix inversion, Matrix diagonalization
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 20 - Curve fitting, Newton Raphson method
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 21 - Random numbers, Numerical integration using Simpson’s rule
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 22 - Numerical Integration and Differential Equations
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 23 - Practical Session on Programming 3: Random numbers, Simpson’s rule; Introduction to Scilab
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 24 - Scilab-2: Matrix equations and Roots of Polynomials
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 25 - Scilab-3: Functions, Integrals, Differential Equations and graphs
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 26 - Scilab-4: Curve Fitting and Execution of Scilab programs
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 27 - Scilab-5: Legendre polynomials, Multiple plots and Curve fitting
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 28 - Scilab-6: Integral Transforms; Introduction to Molecular Dynamics (MD)
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 29 - Classical Molecular Dynamics-2, Force Fields and Equations of Motion
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 30 - Classical Molecular Dynamics-3, Force Fields and MD Algorithms
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 31 - Classical MD-4 Thermodynamic Properties and Distribution Functions.
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 32 - Classical MD-5, Execution of programs on liquid argon
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 33 - Molecular Dynamics using Gromacs-1
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 34 - Molecular Dynamics using Gromacs-2: Simulating Liquid Argon
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 35 - Molecular Dynamics using Gromacs-3: Installing Gromacs
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 36 - Molecular Dynamics using Gromacs-4: Liquid Water: Input Files
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 37 - Molecular Dynamics using Gromacs-5: Liquid Water: Analysis of Results
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 38 - Molecular Dynamics using Gromacs-6: Mixture of Water and Methanol
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 39 - Molecular Dynamics using Gromacs-7: Gromacs Installation
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 40 - Molecular Dynamics using Gromacs-8: Simulation of s-peptide
Link NOC:Computational Chemistry and Classical Molecular Dynamics Lecture 41 - Molecular Dynamics using Gromacs-9: Free Energy of Solvation of Methane, Concluding remarks
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 1 - Frequency Domain Spectroscopy: An Introduction
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 2 - Schematics of Instrumentation for FD Spectroscopy
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 3 - Sensitivity Light Collection and Signal to Noise Ratio
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 4 - Time Domain Spectroscopy
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 5 - Frequency Modulation for Fourier Transform Spectroscopy
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 6 - Rigid Rotor Model for Diatomic Molecules
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 7 - Recapitulation of Quantum Mechanics
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 8 - Conditions for Microwave Activity - I
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 9 - Conditions for Microwave Activity - II
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 10 - Microwave Spectra: Diatomic Molecules
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 11 - Simple Harmonic Oscillator
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 12 - Selection Rule
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 13 - High Resolution IR Spectra
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 14 - Anharmonic Oscillator and Raman Effect
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 15 - Semi Classical Treatment: Radiation-Matter
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 16 - Time Dependent Perturbation Theory
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 17 - Transition Moment Integral
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 18 - Transition Probability and Natural Linewidth
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 19 - Einstein Treatment
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 20 - Relationship Between Theoretical and Experimental Quantities
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 21 - Level System: Concluding Remark - I
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 22 - Level System: Concluding Remark - II
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 23 - Laser Basic
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 24 - Applications of Laser in Spectroscopy
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 25 - Laser in Spectroscopy : Ultrafast Dynamics
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 26 - Snapshot of Bond Breaking
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 27 - Raman Effect
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 28 - Raman Spectroscopy: Quantum Theory of Raman Effect
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 29 - Raman Spectroscopy and Beyond Dipole Approximation
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 30 - Symmetry in Chemistry : An Introduction
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 31 - Symmetry Operations : Transformation Matrices
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 32 - Representations Reducible and Irreducible
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 33 - Matrix Representation of Symmetry Point Group
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 34 - Group Theory : Character Table
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 35 - Character Table : Compendium of Irreducible Representations
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 36 - Mulliken Nomenclature, 2D Irreducible Representations and Bases
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 37 - Character Tables for Different Symmetry Point Groups
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 38 - Wave Functions as Basis
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 39 - Symmetry of Atomic and Molecular Orbitals
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 40 - Polyatomic Molecules : Normal Modes of Vibration
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 41 - Determination of Symmetries of Normal Modes of Vibration - I
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 42 - Determination of Symmetries of Normal Modes of Vibration - II
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 43 - A Shortcut to Symmetry of Normal Modes
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 44 - Normal Modes : Internal Motion IR and Raman Activity
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 45 - IR and Raman Activity - I
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 46 - IR and Raman Activity - II
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 47 - Electronic Spectroscopy : Introduction
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 48 - Electronic Spectra
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 49 - Rotational Fine Structure
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 50 - Symmetry of Electronic States
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 51 - Electronic States of Oxygen
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 52 - Electronic States and Transitions of Benzene
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 53 - Vibronic Coupling
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 54 - Electronic Spectrum of Benzene
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 55 - Basics of NMR Spectroscopy - I
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 56 - Basics of NMR Spectroscopy - II
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 57 - Spin Spin Coupling- AX systems
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 58 - Coupling in A2 systems
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 59 - Coupling in A2 systems (Continued...)
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 60 - NMR: Spectra and Measurement, FT NMR 900 Pulses
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 61 - FT NMR 1800 Pulses and Relaxation Phenomenon
Link NOC:Molecular Spectroscopy: A Physical Chemists Perspective Lecture 62 - Relaxation Phenomenon: Inversion Recovery
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 1 - Transition Metal Allyl and Enyl Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 2 - Transition Metal Allyl and Enyl complexes: Preparation
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 3 - Transition Metal Allyl and Enyl complexes: Preparation
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 4 - Transition Metal Allyl and Enyl Complexes: Reactivity and Transition Metal Sandwich Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 5 - Types of Transition Metal Sandwich Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 6 - Transition Metal Cyclobutadiene Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 7 - Transition Metal Cyclobutadiene Complexes: Preparations
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 8 - Transition Metal Cyclobutadiene Complexes: Reactivity
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 9 - Transition Metal Cyclopentadiene Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 10 - Transition Metal Cyclopentadiene Complexes: Preparation and Properties
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 11 - Transition Metal Cyclopentadiene Complexes: Bonding Properties
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 12 - Transition Metal Cyclopentadiene Complexes: Molecular Orbital Diagram
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 13 - Transition Metal Cyclopentadiene Complexes: Reactivity of Metallocene
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 14 - Transition Metal Cyclopentadiene Complexes: Reactivity of Ferrocene
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 15 - Transition Metal Cyclopentadienyl Carbonyl Complexes: Preparation
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 16 - Transition Metal Cyclopentadienyl Carbonyl Complexes: Reactivity
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 17 - Transition Metal Cyclopentadienyl Nitrosyl Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 18 - Transition Metal Cyclopentadienyl Hydride Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 19 - Transition Metal Cyclopentadienyl Hydride and Halide Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 20 - Transition Metal Cyclopentadienyl Halide Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 21 - Transition Metal Cyclopentadienyl Halide and Transition Metal Arene Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 22 - Transition Metal Arene Complexes: Preparation, Structure and Bonding
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 23 - Transition Metal Arene Complexes: Structure and Bonding
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 24 - Transition Metal Arene Complexes: Reactivity
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 25 - Transition Metal Arene Complexes: Reactivity
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 26 - Transition Metal Arene Carbonyl Complexes: Reactivity
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 27 - Transition Metal Arene Carbonyl Complexes: Reactivity
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 28 - Transition Metal Arene Cyclopentadienyl Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 29 - Transition Metal Arene Cyclopentadienyl and C7H7 Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 30 - Transition Metal C7H7 Complexes: Preparation
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 31 - Transition Metal C7H7 Complexes: Reactivity
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 32 - Transition Metal C8H8 and C7H7 Complexes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 33 - Transition Metal C8H8 Complexes: Properties
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 34 - Transition Metal π- complexes of heterocycles
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 35 - C–C Cross Coupling Reactions
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 36 - C–C Cross Coupling Reactions: Allylic Alkylation
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 37 - C–C Cross Coupling Reactions: Heck Reaction
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 38 - C–C Cross Coupling Reactions: Suzuki Reaction
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 39 - C–C Cross Coupling Reactions: Suzuki Reaction
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 40 - C–C Cross Coupling Reactions: Stille Reaction
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 41 - C–C Cross Coupling Reactions: Stille Coupling
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 42 - C–C Cross Coupling Reactions: Sonogashira Coupling
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 43 - Hydrocyanation Reactions
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 44 - C−heteroatom Coupling
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 45 - C−heteroatom Coupling: Arylamination
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 46 - C−Heteroatom Coupling: Hydroamination
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 47 - C−Heteroatom Coupling: Hydroboration
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 48 - C−Heteroatom Coupling: Hydrosilation
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 49 - Organometallic Catalysis Reactions: Olefin oxidation
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 50 - Organometallic Catalysis Reactions: Olefin oxidation
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 51 - Organometallic Catalysis Reactions: Enantioselective Sharpless Epoxidation
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 52 - Organometallic Catalysis Reactions: Water Gas Shift Reaction
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 53 - Organometallic Catalysis Reactions: Fisher Tropsch Synthesis
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 54 - Organometallic Catalysis Reactions: Fisher Tropsch Mechanism
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 55 - Organometallic Catalysis Reactions: Carbonylation of alcohols
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 56 - Organometallic Catalysis Reactions: Hydrogenation of Alkenes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 57 - Organometallic Catalysis Reactions: Asymmetric Hydrogenation of Alkenes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 58 - Organometallic Catalysis Reactions: Asymmetric Hydrogenation of Alkenes
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 59 - Organometallic Catalysis Reactions: Hydroformylation
Link NOC:Advanced Transition Metal Organometallic Chemistry Lecture 60 - Summary of Advanced Transition Metal Organometallic Chemistry
Link NOC:Mechanisms in Organic Chemistry Lecture 1 - Introduction to Reaction Mechanisms
Link NOC:Mechanisms in Organic Chemistry Lecture 2 - Writing Reaction Mechanisms: Arrow pushing
Link NOC:Mechanisms in Organic Chemistry Lecture 3 - Types of Polar Reactions
Link NOC:Mechanisms in Organic Chemistry Lecture 4 - The Radical Reactions
Link NOC:Mechanisms in Organic Chemistry Lecture 5 - Reaction Co-ordinate Diagrams
Link NOC:Mechanisms in Organic Chemistry Lecture 6 - The Hammond Postulate
Link NOC:Mechanisms in Organic Chemistry Lecture 7 - Kinetic versus Thermodynamic Control
Link NOC:Mechanisms in Organic Chemistry Lecture 8 - Curtin-Hammett Principle
Link NOC:Mechanisms in Organic Chemistry Lecture 9 - An Introduction to Reaction Kinetics
Link NOC:Mechanisms in Organic Chemistry Lecture 10 - Deriving the Rate Laws
Link NOC:Mechanisms in Organic Chemistry Lecture 11 - Distinguishing Reaction Mechanisms Using Rate Laws
Link NOC:Mechanisms in Organic Chemistry Lecture 12 - Methods to Monitor a Reaction
Link NOC:Mechanisms in Organic Chemistry Lecture 13 - The Hammett Equation
Link NOC:Mechanisms in Organic Chemistry Lecture 14 - Linear Free Energy Relationships (LFER)
Link NOC:Mechanisms in Organic Chemistry Lecture 15 - Hammett Plots for Electronic Effects
Link NOC:Mechanisms in Organic Chemistry Lecture 16 - Scales used in Hammett Plots
Link NOC:Mechanisms in Organic Chemistry Lecture 17 - Deviation from Linear Free Energy Relationships
Link NOC:Mechanisms in Organic Chemistry Lecture 18 - LFER for Sterics: The Taft Parameters
Link NOC:Mechanisms in Organic Chemistry Lecture 19 - Solvent Effects - Part A
Link NOC:Mechanisms in Organic Chemistry Lecture 20 - Solvent Effects - Part B
Link NOC:Mechanisms in Organic Chemistry Lecture 21 - Kinetic Isotope Effect
Link NOC:Mechanisms in Organic Chemistry Lecture 22 - Primary Kinetic Isotope Effect
Link NOC:Mechanisms in Organic Chemistry Lecture 23 - Secondary Kinetic Isotope Effect - Part A
Link NOC:Mechanisms in Organic Chemistry Lecture 24 - Secondary Kinetic Isotope Effect - Part B
Link NOC:Mechanisms in Organic Chemistry Lecture 25 - Heavy Atom Isotope Effects
Link NOC:Mechanisms in Organic Chemistry Lecture 26 - Equilibrium Isotope Effects
Link NOC:Mechanisms in Organic Chemistry Lecture 27 - Isotope Labelling
Link NOC:Mechanisms in Organic Chemistry Lecture 28 - Trapping Intermediates - Part A
Link NOC:Mechanisms in Organic Chemistry Lecture 29 - Trapping Intermediates - Part B
Link NOC:Mechanisms in Organic Chemistry Lecture 30 - Trapping Intermediates - Part C
Link NOC:Mechanisms in Organic Chemistry Lecture 31 - Checking for Common Intermediates
Link NOC:Mechanisms in Organic Chemistry Lecture 32 - Catalysis - Part A
Link NOC:Mechanisms in Organic Chemistry Lecture 33 - Catalysis - Part B
Link NOC:Mechanisms in Organic Chemistry Lecture 34 - Specific Catalysis
Link NOC:Mechanisms in Organic Chemistry Lecture 35 - General Catalysis - Part A
Link NOC:Mechanisms in Organic Chemistry Lecture 36 - General Catalysis - Part B
Link NOC:Mechanisms in Organic Chemistry Lecture 37 - Enzyme Catalysis
Link NOC:Mechanisms in Organic Chemistry Lecture 38 - Electrophilic Catalysis
Link NOC:Mechanisms in Organic Chemistry Lecture 39 - Other Types of Catalysis
Link NOC:Mechanisms in Organic Chemistry Lecture 40 - Course Summary
Link NOC:Metals in Biology Lecture 1 - Importance of metals in biology
Link NOC:Metals in Biology Lecture 2 - Choice, uptake and assembly of metal ions in cells
Link NOC:Metals in Biology Lecture 3 - Control and use of metal ions concentration in biological systems
Link NOC:Metals in Biology Lecture 4 - Metal mediated folding of biopolymers
Link NOC:Metals in Biology Lecture 5 - Study of binding mode of calcium and zinc in proteins
Link NOC:Metals in Biology Lecture 6 - Electron transfer (ET) in living systems
Link NOC:Metals in Biology Lecture 7 - Oxygen transport and activation
Link NOC:Metals in Biology Lecture 8 - Hydrolytic Enzymes - Part I - Carbonic anhydrase and Liver alcohol dehydrogenase
Link NOC:Metals in Biology Lecture 9 - Hydrolytic Enzymes - Part II - Carbopeptidase
Link NOC:Metals in Biology Lecture 10 - Hydrolytic Enzymes - Part III - Arginase and Urease
Link NOC:Metals in Biology Lecture 11 - Hemerythrin and azidomethemerythrin
Link NOC:Metals in Biology Lecture 12 - Dioxygen reactivity in copper
Link NOC:Metals in Biology Lecture 13 - Cu-O2 intermediates
Link NOC:Metals in Biology Lecture 14 - Copper-Oxygen chemistry - Part I - Mononuclear copper-oxygen
Link NOC:Metals in Biology Lecture 15 - Copper-Oxygen chemistry - Part II - Cu-O2 complexes
Link NOC:Metals in Biology Lecture 16 - Copper-Oxygen chemistry - Part III - Reactivity summary
Link NOC:Metals in Biology Lecture 17 - Iron Catalyzed oxidation of unactivated sp3 C-H bonds - Part I
Link NOC:Metals in Biology Lecture 18 - Iron catalyzed oxidation of unactivated sp3 C-H bonds - Part II
Link NOC:Metals in Biology Lecture 19 - Iron catalyzed oxidation of unactivated sp3 C-H bonds - Part III
Link NOC:Metals in Biology Lecture 20 - Nitrous oxide reductase and its model complex
Link NOC:Metals in Biology Lecture 21 - Cytochrome C-oxidase
Link NOC:Metals in Biology Lecture 22 - Systematic variations in O-O stretch in Iron-oxo-copper ligand complex
Link NOC:Metals in Biology Lecture 23 - Mononuclear nonheme iron (NHI) enzymes
Link NOC:Metals in Biology Lecture 24 - Alpha-Keto Glutarate dependent Halogenases
Link NOC:Metals in Biology Lecture 25 - Cytochrome P450 - Part I - Introduction
Link NOC:Metals in Biology Lecture 26 - Cytochrome P450 - Part II - Reactions
Link NOC:Metals in Biology Lecture 27 - Cytochrome P450 - Part III - Mechanism
Link NOC:Metals in Biology Lecture 28 - Cytochrome P450 - Part IV - Role of Cystine ligand and distal charge relay
Link NOC:Metals in Biology Lecture 29 - Methane monooxygenase
Link NOC:Metals in Biology Lecture 30 - Dinuclear Iron active sites for CH4 to CH4OH conversion and its Mechanism
Link NOC:Metals in Biology Lecture 31 - Concerted Vs radical pathway for CH4 to CH4OH conversion
Link NOC:Metals in Biology Lecture 32 - Photosynthesis - Part I
Link NOC:Metals in Biology Lecture 33 - Photosynthesis - Part II
Link NOC:Metals in Biology Lecture 34 - Pumps and channels
Link NOC:Metals in Biology Lecture 35 - Quick summary on O2 transport
Link NOC:Metals in Biology Lecture 36 - Summary of Dioxygen reactivity in copper
Link NOC:Metals in Biology Lecture 37 - Summary of Dioxygen reactivity in iron
Link NOC:Metals in Biology Lecture 38 - Summary of Fe-O2 chemistry
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 1 - Basic concepts
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 2 - Resonance absorption
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 3 - Bloch Equations
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 4 - Relaxation
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 5 - Introduction to Chemical Shift
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 6 - Factors affecting Isotropic Chemical Shifts
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 7 - Spin-Spin Coupling
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 8 - Interpretation of multiplet structure using first order analysis
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 9 - Analysis of NMR spectra of molecules
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 10 - Quantum Mechanical Analysis - Part I
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 11 - Quantum Mechanical Analysis - Part II
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 12 - Dynamic effects in the NMR Spectra
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 13 - Fourier Transform NMR
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 14 - Theorems on Fourier Transform
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 15 - Practical aspects of Fourier Transform NMR spectra
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 16 - Data Processing in Fourier Transform NMR
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 17 - Dynamic range in Fourier Transform NMR
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 18 - Spin Echo and Solvent Suppression
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 19 - Spin Decoupling in FT NMR and Relaxation Measurements
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 20 - Polarization Transfer
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 21 - Nuclear Overhauser Effect
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 22 - Steady state NOE and Transient NOE
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 23 - Distance and NOE
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 24 - Selective Population Inversion
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 25 - INEPT and Sensitivity Enhancement
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 26 - Rotating Frame Experiments
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 27 - Density matrix description of NMR - I
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 28 - Density matrix description of NMR - II
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 29 - Density matrix description of NMR - III
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 30 - Time evolution of density operator
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 31 - Density matrix description of NMR - IV
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 32 - Evolution of density operator in the presence of RF
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 33 - Product operator formalism
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 34 - Product operator formalism (Continued...)
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 35 - Product operator formalism (Continued...)
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 36 - Time evolution of basis operators
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 37 - Observable and Non-observable basis operators, Spin echo
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 38 - Spin echo (Continued...)
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 39 - INEPT
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 40 - Multidimensional NMR Spectroscopy
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 41 - Two Dimensional NMR - Part I
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 42 - Two Dimensional NMR - Part II
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 43 - Types of 2D NMR Spectra
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 44 - Two Dimensional Separation of Interaction in NMR
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 45 - Two Dimensional Correlation Experiments - I
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 46 - Two Dimensional Correlation Experiments - II
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 47 - Two Dimensional Correlation Experiments - III
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 48 - Double Quantum Filtered COSY (DQF-COSY)
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 49 - Two Dimensional Nuclear Overhauser Effect Spectroscopy (2D- NOESY)
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 50 - Constant-time COSY
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 51 - Scaling in 2D NMR
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 52 - Total Correlation Spectroscopy
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 53 - 2D Heteronuclear Experiment - I
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 54 - 2D Heteronuclear Experiment - II
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 55 - Multidimensional NMR
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 56 - Structure Determination of Peptides by NMR - I
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 57 - Structure Determination of Peptides by NMR - II
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 58 - Protein-Ligand Interaction - I
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 59 - Protein-Ligand Interaction - II
Link NOC:NMR Spectroscopy for Chemists and Biologists Lecture 60 - Diffusion Ordered Spectroscopy
Link NOC:Basics in Inorganic Chemistry Lecture 1 - Concept of Effective Nuclear Charge
Link NOC:Basics in Inorganic Chemistry Lecture 2 - Electronic Configuration of Elements
Link NOC:Basics in Inorganic Chemistry Lecture 3 - Properties of Elements (Size, IE, EA and EN)
Link NOC:Basics in Inorganic Chemistry Lecture 4 - Extraction of Metals
Link NOC:Basics in Inorganic Chemistry Lecture 5 - Ellingham Diagram
Link NOC:Basics in Inorganic Chemistry Lecture 6 - Thermit Process and Zone Refining
Link NOC:Basics in Inorganic Chemistry Lecture 7 - Coordination Chemistry: 18 electron rule and VBT
Link NOC:Basics in Inorganic Chemistry Lecture 8 - Crystal Field Theory: Octahedral Complex
Link NOC:Basics in Inorganic Chemistry Lecture 9 - Crystal Field Theory: Tetrahedral Complex
Link NOC:Basics in Inorganic Chemistry Lecture 10 - Crystal Field Theory: Octahedral vs. Tetrahedral Complex
Link NOC:Basics in Inorganic Chemistry Lecture 11 - Application of CFSE: Spinel and J-T Distortion
Link NOC:Basics in Inorganic Chemistry Lecture 12 - Introduction to Molecular Magnetism
Link NOC:Basics in Inorganic Chemistry Lecture 13 - Problem Solving Approach
Link NOC:Basics in Inorganic Chemistry Lecture 14 - Magnetism
Link NOC:Basics in Inorganic Chemistry Lecture 15 - Spectroscopic Term Symbol
Link NOC:Basics in Inorganic Chemistry Lecture 16 - Magnetic States of Matter: Paramagnetic, Ferro and Antiferromagnetic
Link NOC:Basics in Inorganic Chemistry Lecture 17 - Introduction to Bio-Inorganic Chemistry
Link NOC:Basics in Inorganic Chemistry Lecture 18 - Metalloprotein (Hb, Mb, Transferrin) and Metalloenzyme (Plastocyanin)
Link NOC:Basics in Inorganic Chemistry Lecture 19 - Oxygen Transportation Mechanism
Link NOC:Ultrafast Laser Spectroscopy Lecture 1 - Introduction
Link NOC:Ultrafast Laser Spectroscopy Lecture 2 - Steady State Spectra
Link NOC:Ultrafast Laser Spectroscopy Lecture 3 - Spectro Photometer
Link NOC:Ultrafast Laser Spectroscopy Lecture 4 - How to record Absorption and Emission Spectra
Link NOC:Ultrafast Laser Spectroscopy Lecture 5 - Excited state processes
Link NOC:Ultrafast Laser Spectroscopy Lecture 6 - TCSPC for picosecond- Nanosecond Time Domain
Link NOC:Ultrafast Laser Spectroscopy Lecture 7 - TCSPC for picosecond- Nanosecond Time Domain (Continued...)
Link NOC:Ultrafast Laser Spectroscopy Lecture 8 - TCSPC Lab
Link NOC:Ultrafast Laser Spectroscopy Lecture 9 - Data Fitting 1
Link NOC:Ultrafast Laser Spectroscopy Lecture 10 - Data Fitting 2
Link NOC:Ultrafast Laser Spectroscopy Lecture 11 - Femtosecond Fluorescence Upconversion - 1
Link NOC:Ultrafast Laser Spectroscopy Lecture 12 - Femtosecond Fluorescence Upconversion - 2
Link NOC:Ultrafast Laser Spectroscopy Lecture 13 - Femtosecond Fluorescence Upconversion - 3
Link NOC:Ultrafast Laser Spectroscopy Lecture 14 - FOG Lab
Link NOC:Ultrafast Laser Spectroscopy Lecture 15 - Gate Detectors and Streak Camera - Part 1
Link NOC:Ultrafast Laser Spectroscopy Lecture 16 - Gate Detectors and Streak Camera - Part 2
Link NOC:Ultrafast Laser Spectroscopy Lecture 17 - Stimulated Emission
Link NOC:Ultrafast Laser Spectroscopy Lecture 18 - Two Level System
Link NOC:Ultrafast Laser Spectroscopy Lecture 19 - 3 and 4 level system
Link NOC:Ultrafast Laser Spectroscopy Lecture 20 - From CW to Pulsed Laser
Link NOC:Ultrafast Laser Spectroscopy Lecture 21 - Longitudinal modes
Link NOC:Ultrafast Laser Spectroscopy Lecture 22 - Modelocking for short pulses
Link NOC:Ultrafast Laser Spectroscopy Lecture 23 - Modelocking for short pulses (Continued...)
Link NOC:Ultrafast Laser Spectroscopy Lecture 24 - Kerr lens Modelocking for femtosecond pulses
Link NOC:Ultrafast Laser Spectroscopy Lecture 25 - Titanium Sapphire lasers
Link NOC:Ultrafast Laser Spectroscopy Lecture 26 - Active and Passive Modelocking
Link NOC:Ultrafast Laser Spectroscopy Lecture 27 - Modelocking and cavity damping
Link NOC:Ultrafast Laser Spectroscopy Lecture 28 - Ti:Sapphire laser (Lab visit)
Link NOC:Ultrafast Laser Spectroscopy Lecture 29 - Cavity Dumping
Link NOC:Ultrafast Laser Spectroscopy Lecture 30 - Cavity dumping (Continued...)
Link NOC:Ultrafast Laser Spectroscopy Lecture 31 - Q switching
Link NOC:Ultrafast Laser Spectroscopy Lecture 32 - Stretching and compressing ultrafast laser pulses
Link NOC:Ultrafast Laser Spectroscopy Lecture 33 - Pulse stretcher/Compressor: Single Grating
Link NOC:Ultrafast Laser Spectroscopy Lecture 34 - Chirped pulsed amplification
Link NOC:Ultrafast Laser Spectroscopy Lecture 35 - Oscillators and Amplifier: Design and materials
Link NOC:Ultrafast Laser Spectroscopy Lecture 36 - Alexandrite and fibril lasers
Link NOC:Ultrafast Laser Spectroscopy Lecture 37 - Regenerative amplifier in our lab
Link NOC:Ultrafast Laser Spectroscopy Lecture 38 - Brief overview of nonlinear optical phenomena
Link NOC:Ultrafast Laser Spectroscopy Lecture 39 - Brief overview of nonlinear optical phenomena (Continued...)
Link NOC:Ultrafast Laser Spectroscopy Lecture 40 - Brief overview of nonlinear optical phenomena (Continued...)
Link NOC:Ultrafast Laser Spectroscopy Lecture 41 - SFG and SHG with ultrafast pulses
Link NOC:Ultrafast Laser Spectroscopy Lecture 42 - SFG and SHG with ultrafast pulses (Continued...)
Link NOC:Ultrafast Laser Spectroscopy Lecture 43 - Optical parametric generation and amplification
Link NOC:Ultrafast Laser Spectroscopy Lecture 44 - OPA in our lab TOPAS C - Part 1
Link NOC:Ultrafast Laser Spectroscopy Lecture 45 - OPA in our lab TOPAS C - Part 2
Link NOC:Ultrafast Laser Spectroscopy Lecture 46 - OPA in our lab TOPAS C - Part 3
Link NOC:Ultrafast Laser Spectroscopy Lecture 47 - Snapshots of bond breaking
Link NOC:Ultrafast Laser Spectroscopy Lecture 48 - Twisted Intramolecular Charge Transfer - Part 1
Link NOC:Ultrafast Laser Spectroscopy Lecture 49 - Twisted Intramolecular Charge Transfer - Part 2
Link NOC:Ultrafast Laser Spectroscopy Lecture 50 - Solvation dynamics - Part 1
Link NOC:Ultrafast Laser Spectroscopy Lecture 51 - Solvation dynamics - Part 2
Link NOC:Ultrafast Laser Spectroscopy Lecture 52 - Vibrational energy transfer in water
Link NOC:Ultrafast Laser Spectroscopy Lecture 53 - Excited state proton transfer: Introduction
Link NOC:Ultrafast Laser Spectroscopy Lecture 54 - Excited state double proton transfer of 7-Azaindole dimer - 1
Link NOC:Ultrafast Laser Spectroscopy Lecture 55 - Excited state double proton transfer of 7-Azaindole dimer - 2
Link NOC:Ultrafast Laser Spectroscopy Lecture 56 - Excited state double proton transfer of 7-Azaindole dimer - 3
Link NOC:Ultrafast Laser Spectroscopy Lecture 57 - Plasmonic nanoparticles - 1
Link NOC:Ultrafast Laser Spectroscopy Lecture 58 - Plasmonic nanoparticles - 2
Link NOC:Ultrafast Laser Spectroscopy Lecture 59 - Nanoclusters
Link NOC:Ultrafast Laser Spectroscopy Lecture 60 - Semiconductor Nanocrystals - Part 1
Link NOC:Ultrafast Laser Spectroscopy Lecture 61 - Semiconductor nanocrystals - Part 2
Link NOC:Ultrafast Laser Spectroscopy Lecture 62 - Radiative and Nonradiative Relaxation Pathways in CdSe Nanocrystals - Part 1
Link NOC:Ultrafast Laser Spectroscopy Lecture 63 - Radiative and Nonradiative Relaxation Pathways in CdSe Nanocrystals - Part 2
Link NOC:Ultrafast Laser Spectroscopy Lecture 64 - Multiexciton in semiconductor nanocrystals - Part 1
Link NOC:Ultrafast Laser Spectroscopy Lecture 65 - Multiexciton in semiconductor nanocrystals - Part 2
Link NOC:Ultrafast Laser Spectroscopy Lecture 66 - Two dimensional Infrared spectroscopy: Introduction
Link NOC:Ultrafast Laser Spectroscopy Lecture 67 - 2DIR: Techniques
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 1 - Introduction
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 2 - Reppe Synthesis (Introduction)
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 3 - Reppe Reactions - Part 1
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 4 - Reppe Reactions - Part 2
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 5 - Reppe Reactions - Part 3
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 6 - Metallative and Conventional Reppeand Metathesis Reaction (Introduction)
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 7 - Origin of Olefin Metathesis
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 8 - Mechanistic approaches of Metathesis Reaction - Part 1
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 9 - Mechanistic approaches of Metathesis Reaction - Part 2
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 10 - Mechanistic approaches of Metathesis Reaction - Part 3
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 11 - Mechanistic approaches of Metathesis Reaction - Part 4
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 12 - Types of Carbenes
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 13 - Types of Metathesis Reactions
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 14 - Alkyne Metathesis
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 15 - Catalysis Development Aspect of Olefin Metathesis - Part 1
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 16 - Catalysis Development Aspect of Olefin Metathesis - Part 2
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 17 - Catalysis Development Aspect of Olefin Metathesis - Part 3
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 18 - Catalysis Development Aspect of Olefin Metathesis - Part 4
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 19 - Cross Metathesis - Part 1
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 20 - Cross Metathesis - Part 2
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 21 - Cross Metathesis - Part 3
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 22 - Ring Opening Metathesis - Part 1
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 23 - Ring Opening Metathesis - Part 2
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 24 - Ring Opening Metathesis - Part 3
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 25 - Ring Closing Metathesis - Part 1
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 26 - Ring Closing Metathesis - Part 2
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 27 - Ring Closing Metathesis - Part 3
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 28 - Alkyne Metathesis
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 29 - Alkene Alkyne Metathesis - Part 1
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 30 - Alkene Alkyne Metathesis - Part 2
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 31 - Alkene Alkyne Metathesis - Part 3
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 32 - Ring Closing Eneyne Metathesis (RCEYM) - Part 1
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 33 - Ring Closing Eneyne Metathesis (RCEYM) - Part 2
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 34 - Ring Closing Eneyne Metathesis (RCEYM) and Alkenes and Alkynes oligomerization reactions
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 35 - Oligomerization of alkenes and alkynes - Part 1
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 36 - Oligomerization of alkenes and alkynes - Part 2
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 37 - Oligomerization of alkenes and alkynes - Part 3
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 38 - Oligomerization of alkenes and alkynes - Part 4
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 39 - Alkene oligomerization and Polymerization.
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 40 - Olefin Polymerization - Part 1
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 41 - Olefin Polymerization - Part 2
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 42 - Olefin Polymerization - Part 3
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 43 - Olefin Polymerization - Part 4
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 44 - Olefin Polymerization - Part 5
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 45 - Olefin Polymerization - Part 6
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 46 - Olefin Polymerization - Part 7
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 47 - Olefin Polymerization - Part 8
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 48 - Olefin Polymerization - Part 9
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 49 - Olefin Polymerization - Part 10
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 50 - Olefin Polymerization - Part 11
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 51 - Olefin Polymerization - Part 12
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 52 - Olefin Polymerization - Part 13
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 53 - Olefin Polymerization - Part 14
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 54 - Olefin Polymerization - Part 15
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 55 - Olefin Polymerization - Part 16
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 56 - Homo and Copolymerization; Functionalized olefins, Cycloolefins and Diolefins
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 57 - Non- Group IV Metal based olefin polymerization catalysts
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 58 - Non- Group IV Metal based olefin polymerization catalysts
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 59 - Bioorganometallic Chemistry
Link NOC:Transition Metal Organometallics in Catalysis and Biology Lecture 60 - Overall summary of Transition metal organometallics in catalysis and biology
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 1 - Basic Introduction
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 2 - Bohr Model and Beyond
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 3 - The wave nature of matter
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 4 - Ground Rules: Postulates of Quantum mechanics - Part I
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 5 - Ground Rules: Postulates of Quantum mechanics - Part II
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 6 - Particle in a box - Part I
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 7 - Particle in a box - Part II
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 8 - Particle in a box - Part III
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 9 - Particle in a box - Uncertainity Priciple
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 10 - Particle in a box - Uncertainity Priciple (Continued...)
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 11 - Quantum Mechanical Tunneling
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 12 - Harmonic Oscillator - Part 1
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 13 - Harmonic Oscillator - Part 2
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 14 - Harmonic Oscillator - Part 3
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 15 - Harmonic Oscillators - Wave Functions and Recursion formulae
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 16 - Harmonic Oscillators - Wave Functions and Recursion formulae (Continued...)
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 17 - Harmonic Oscillators: Conclusions
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 18 - Rigid Rotor - Part 1
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 19 - Rigid Rotor - Part 2
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 20 - Rigid Rotor - Part 3
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 21 - Polar Plots of Spherical Harmonics
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 22 - Angular Momentum
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 23 - Angular Momentum (Continued...)
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 24 - Hydrogen Atom: Schrodinger Equation
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 25 - Hydrogen Atom: Schrodinger Equation (Continued...)
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 26 - Hydrogen atom: Quantum numbers
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 27 - Radial Probability distribution functions
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 28 - Hydrogen atom wavefunctions: s orbitals
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 29 - 2s orbital
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 30 - 2p orbitals
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 31 - 3pz and 3d orbitals
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 32 - Atomic orbitals and orbital approximation
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 33 - Multi electron atoms
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 34 - He atom wavefunction
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 35 - Excited states of many electron atoms
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 36 - Introduction to Perturbation theory
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 37 - Scope of Perturbation theory
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 38 - Application of Perturbation theory: Anharmonic oscillator
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 39 - Higher order perturbations
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 40 - Perturbation theory for non-degenerate states
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 41 - Perturbation Theory for degenerate states
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 42 - Application of Perturbation Theory for degenerate States
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 43 - Variation Method
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 44 - Variational Method (Continued...)
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 45 - Variational calculations for Harmonic Oscillator and Particle in a Box
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 46 - Secular equations in Variational calculations
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 47 - Secular equations for particle in a box
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 48 - Variational calculation for particle in a box (Continued...)
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 49 - Perturbation theory for many electron atoms
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 50 - Variational method for many electron atoms
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 51 - Hartree-Fock Equations and Self Consistent Fields
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 52 - Hartree-Fock Equations for He - Part 1
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 53 - Hartree-Fock Equations for He - Part 2
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 54 - Electronic Wavefunctions of He atom
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 55 - Valance Bond Theory and homonuclear diatomics - Part 1
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 56 - Valance Bond Theory and homonuclear diatomics - Part 2
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 57 - Molecular shape and hybrid orbitals
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 58 - sp2 hybridization
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 59 - sp3 hybridization
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 60 - Non-equivalent hybrid orbitals
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 61 - Molecular Orbital Theory for H2+
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 62 - Molecular orbital theory for homonuclear diatomic molecules
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 63 - Beyond Homonuclear diatomic molecules
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 64 - MOT for polyatomic molecules
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 65 - Huckel MOT-1
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 66 - Huckel MOT-2
Link NOC:Quantum Chemistry of Atoms and Molecules Lecture 67 - The last word
Link NOC:Basic Statistical Mechanics Lecture 1 - Why Study Statistical Mechanics?
Link NOC:Basic Statistical Mechanics Lecture 2 - Thermodynamics
Link NOC:Basic Statistical Mechanics Lecture 3 - Probability Theory - Part 1
Link NOC:Basic Statistical Mechanics Lecture 4 - Probability Theory - Part 2
Link NOC:Basic Statistical Mechanics Lecture 5 - Fundamental concepts and Postulates of Statistical Mechanics - Part 1
Link NOC:Basic Statistical Mechanics Lecture 6 - Fundamental concepts and Postulates of Statistical Mechanics - Part 2
Link NOC:Basic Statistical Mechanics Lecture 7 - From Postulates to Formulation
Link NOC:Basic Statistical Mechanics Lecture 8 - Microcanonical Ensemble
Link NOC:Basic Statistical Mechanics Lecture 9 - Relation with Thermodynamics in Microcanonical Ensemble - Part 1
Link NOC:Basic Statistical Mechanics Lecture 10 - Relation with Thermodynamics in Microcanonical Ensemble - Part 2
Link NOC:Basic Statistical Mechanics Lecture 11 - Canonical Ensemble - Part 1
Link NOC:Basic Statistical Mechanics Lecture 12 - Canonical Ensemble - Part 2
Link NOC:Basic Statistical Mechanics Lecture 13 - Thermodynamic Potential for Canonical ensemble
Link NOC:Basic Statistical Mechanics Lecture 14 - Grand Canonical Ensemble
Link NOC:Basic Statistical Mechanics Lecture 15 - Thermodynamic Potentials for Grand Canonical and Isothermal-Isobaric ensembles
Link NOC:Basic Statistical Mechanics Lecture 16 - Fluctuations and Response Function - Part 1
Link NOC:Basic Statistical Mechanics Lecture 17 - Fluctuations and Response Function - Part 2
Link NOC:Basic Statistical Mechanics Lecture 18 - Ideal Monatomic Gas: Microscopic Expression of Translational Entropy - Part 1
Link NOC:Basic Statistical Mechanics Lecture 19 - Ideal Monatomic Gas: Microscopic Expression of Translational Entropy - Part 2
Link NOC:Basic Statistical Mechanics Lecture 20 - Ideal Monatomic Gas: Microscopic Expression of Translational Entropy - Part 3
Link NOC:Basic Statistical Mechanics Lecture 21 - Ideal Monatomic Gas: Microscopic Expression of Translational Entropy - Part 4
Link NOC:Basic Statistical Mechanics Lecture 22 - Ideal Monatomic Gas: Microscopic Expression of Translational Entropy - Part 5
Link NOC:Basic Statistical Mechanics Lecture 23 - Ideal Gas of Diatomic Molecules: Microscopic Expression for Rotational and Vibrational Entropy and Specific Heat - Part 1
Link NOC:Basic Statistical Mechanics Lecture 24 - Ideal Gas of Diatomic Molecules: Microscopic Expression for Rotational and Vibrational Entropy and Specific Heat - Part 2
Link NOC:Basic Statistical Mechanics Lecture 25 - Ideal Gas of Diatomic Molecules: Microscopic Expression for Rotational and Vibrational Entropy and Specific Heat - Part 3
Link NOC:Basic Statistical Mechanics Lecture 26 - Ideal Gas of Diatomic Molecules: Microscopic Expression for Rotational and Vibrational Entropy and Specific Heat - Part 4
Link NOC:Basic Statistical Mechanics Lecture 27 - Ideal Gas of Polyatomic molecules
Link NOC:Basic Statistical Mechanics Lecture 28 - Cluster Expansion and Mayer’s Theory of Condensation - Part 1
Link NOC:Basic Statistical Mechanics Lecture 29 - Cluster Expansion and Mayer’s Theory of Condensation - Part 2
Link NOC:Basic Statistical Mechanics Lecture 30 - Cluster Expansion and Mayer’s Theory of Condensation - Part 3
Link NOC:Basic Statistical Mechanics Lecture 31 - Cluster Expansion and Mayer’s Theory of Condensation - Part 4
Link NOC:Basic Statistical Mechanics Lecture 32 - Cluster Expansion and Mayer’s Theory of Condensation - Part 5
Link NOC:Basic Statistical Mechanics Lecture 33 - Cluster Expansion and Mayer’s Theory of Condensation - Part 6
Link NOC:Basic Statistical Mechanics Lecture 34 - Phase Transition and Landau Theory - Part 1
Link NOC:Basic Statistical Mechanics Lecture 35 - Phase Transition and Landau Theory - Part 2
Link NOC:Basic Statistical Mechanics Lecture 36 - Phase Transition and Landau Theory - Part 3
Link NOC:Basic Statistical Mechanics Lecture 37 - Comments on some important Concepts of Statistical Mechanics
Link NOC:Basic Statistical Mechanics Lecture 38 - Nucleation Part 1: Introduction, Thermodynamics of Nucleation
Link NOC:Basic Statistical Mechanics Lecture 39 - Nucleation Part 2: Kinetics of Nucleation
Link NOC:Basic Statistical Mechanics Lecture 40 - Nucleation Part 3: Kinetics of Nucleation, Classical Nucleation Theory, Heterogeneous Nucleation
Link NOC:Basic Statistical Mechanics Lecture 41 - Nucleation Part 4: Ostwald Step Rule
Link NOC:Basic Statistical Mechanics Lecture 42 - Spinodal Decomposition and Pattern Formation: Evolution of Structure through Dynamics - Part 1
Link NOC:Basic Statistical Mechanics Lecture 43 - Spinodal Decomposition and Pattern Formation: Evolution of Structure through Dynamics - Part 2
Link NOC:Basic Statistical Mechanics Lecture 44 - Ising Model and Other Lattice Models - Part 1
Link NOC:Basic Statistical Mechanics Lecture 45 - Ising Model and Other Lattice Models - Part 2
Link NOC:Basic Statistical Mechanics Lecture 46 - Ising Model and Other Lattice Models - Part 3
Link NOC:Basic Statistical Mechanics Lecture 47 - Ising Model and Other Lattice Models - Part 4
Link NOC:Basic Statistical Mechanics Lecture 48 - Ising Model and Other Lattice Models - Part 5
Link NOC:Basic Statistical Mechanics Lecture 49 - Binary Mixtures: Towards Understanding Non-Ideality and Osmotic Pressure - Part 1
Link NOC:Basic Statistical Mechanics Lecture 50 - Binary Mixtures: Towards Understanding Non-Ideality and Osmotic Pressure - Part 2
Link NOC:Basic Statistical Mechanics Lecture 51 - Theory of Liquids - Part 1
Link NOC:Basic Statistical Mechanics Lecture 52 - Theory of Liquids - Part 2
Link NOC:Basic Statistical Mechanics Lecture 53 - Theory of Liquids - Part 3
Link NOC:Basic Statistical Mechanics Lecture 54 - Theory of Liquids - Part 4
Link NOC:Basic Statistical Mechanics Lecture 55 - Polymers in Solution and Polymer Collapse - Part 1
Link NOC:Basic Statistical Mechanics Lecture 56 - Polymers in Solution and Polymer Collapse - Part 2
Link NOC:Basic Statistical Mechanics Lecture 57 - Polymers in Solution and Polymer Collapse - Part 3
Link NOC:Basic Statistical Mechanics Lecture 58 - Polymers in Solution and Polymer Collapse - Part 4
Link NOC:Basic Statistical Mechanics Lecture 59 - Computer Simulation Methods in Statistical Mechanics - Part 1
Link NOC:Basic Statistical Mechanics Lecture 60 - Computer Simulation Methods in Statistical Mechanics - Part 2
Link NOC:Basic Statistical Mechanics Lecture 61 - Conclusion
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 1 - Introduction to quantum Mechanics - Part 1
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 2 - Introduction to quantum Mechanics - Part 2
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 3 - Introduction to quantum Mechanics - Part 3
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 4 - Time Dependant Perturbation Theory of Two states - Part 1
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 5 - Time Dependent Perturbation Theory of Two States - Part 2
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 6 - Time Dependent Perturbation Theory of Two States - Part 3
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 7 - Time Dependent Perturbation Theory of Many States - Part 1
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 8 - Time Dependent Perturbation Theory of Many States - Part 2
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 9 - First-Order Correction to Time- Dependent Perturbation Theory
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 10 - Properties of Light (Classical Treatment)
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 11 - Interaction Hamiltonian - Part 1
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 12 - Interaction Hamiltonian - Part 2
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 13 - Interaction Hamiltonian - Part 3
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 14 - Transition Moment Integral
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 15 - Absorption Probability - Part 1
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 16 - Absorption Probability - Part 2
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 17 - Transition to Continuum States: Fermi’s Golden Rule
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 18 - Einstein’s Coefficient - Part 1
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 19 - Einstein’s Coefficient - Part 2
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 20 - Einstein’s Coefficient - Part 3
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 21 - Spontaneous Emission Lifetime
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 22 - Relationship between Transition Dipole and Extinction Coefficient
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 23 - Spectral Lineshapes
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 24 - Selection Rules
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 25 - Molecular Rotations - Part 1
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 26 - Molecular Rotations - Part 2
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 27 - Molecular Rotations - Part 3
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 28 - Rotational Selection Rules
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 29 - Rotational Spectrum
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 30 - Molecular Vibrations - Part 1
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 31 - Molecular Vibrations - Part 2
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 32 - Vibrational Selection rules
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 33 - Electronic Transition
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 34 - Rotations of Polyatomic Molecules - Part 1
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 35 - Rotations of Polyatomic Molecules - Part 2
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 36 - Selection Rules for particle in a box
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 37 - Interpretation of Rotational Spectra
Link NOC:Quantum Mechanics and Molecular Spectroscopy Lecture 38 - Features of vibrational and electronic spectroscopy
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 1 - Introduction to organic synthesis-Importance of selectivity, stereochemistry and Mechanism
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 2 - Sulfur based oxidations of alcohols
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 3 - Sulfur based oxidations and Pummerer rearrangement
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 4 - Further aspects of sulfur and selenium based oxidations
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 5 - Organoselenium chemistry and SeO2 based oxidations
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 6 - SeO2 based oxidation of ketones and Sulfoxide- Sulfenate rearrangement (Mislow-Evans rearrangement)
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 7 - Mechanistic and stereochemical aspects of Mislow-Evans rearrangement and synthetic applications
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 8 - Further synthetic applications of Mislow-Evans rearrangement and Saegusa-Ito oxidation
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 9 - 1,2-Ketone transpositions, Shapiro reaction and Dauben-Michno rearrangement (a case of 1,3-enone transposition)
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 10 - Dess-Martin periodinane oxidation
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 11 - Iodoxybenzoic acid (IBX) based oxidations
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 12 - Silver based oxidations: Prevost reaction and use of Fetizon’s reagent
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 13 - Further aspects of oxidations using Fetizon’s reagent: Mechanism and Stereochemistry
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 14 - Ruthenium tetroxide (and RuCl3/NaIO4) mediated oxidations
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 15 - Tetra-n-propylammonium perruthenate (TPAP) based oxidations, and Tamao-Fleming oxidation
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 16 - Further synthetic and mechanistic aspects of Tamao-Fleming oxidations
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 17 - Oxidations with dimethyl dioxirane (DMDO)
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 18 - Mechanistic aspects of DMDO based oxidations and oxaziridine mediated alpha-hydroxylations of ketones
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 19 - Asymmetric alpha-hydroxylations using oxaziridine based reactions
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 20 - Barton and related reactions (oxidation at unfunctionalised carbons) and synthetic applications
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 21 - beta-Cleavage in Barton and related reactions and miscellaneous oxidations such as TEMPO based oxidations, Pinnick oxidation and pseudomonas putida mediated oxidations
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 22 - Reductions in organic chemistry: Metal hydride (NaBH4 and LiAlH4) mediated reduction
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 23 - Reductions using diisobutylaluminum hydride (DIBAL-H)
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 24 - Further aspects of DIBAL-H based reductions and comparison with mixed chloride hydrides
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 25 - Reductions with Red-Al, and Luche Reductions
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 26 - Further aspects of Luche reduction, stereochemistry in reductions and reduction with LiBH4
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 27 - Reductions with Zn(BH4)2, LiBHEt3 (superhydride) and L and K-selectrides
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 28 - Reductions with LS/KS selectrides and NaCNBH3
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 29 - Dissolving metal reductions (Na, K, Mg) and McMurry coupling using Ti(0)
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 30 - Stereochemistry and mechanistic aspects of McMurry coupling and metal mediated reductions of alpha, beta-unsaturated ketones
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 31 - Silanes [R3SiH, including polymethylhydrosiloxanes (PMHS)] as reducing agents
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 32 - Further aspects of silanes as reducing agents and Barton-McCombie deoxygenation
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 33 - Tributyltinhydride (n-Bu3SnH) based radical based reductions and C-C bond formations
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 34 - Asymmetric synthesis: An introduction
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 35 - Sharpless asymmetric epoxidation: Mechanism, stereochemistry and kinetic resolution
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 36 - Synthetic utility of chiral 2,3-epoxy alcohols obtained from Sharpless epoxidation
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 37 - Katsuki-Jacobsen epoxidation: Mechanism and stereochemistry
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 38 - Further aspects of Katsuki-Jacobsen epoxidation, and Introduction to Sharpless Asymmetric Dihydroxylation
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 39 - Mechanism, stereochemical aspects and synthetic applications of Sharpless Asymmetric Dihydroxylation
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 40 - Asymmetric hydrogenations and reductions using rhodium and ruthenium derived chiral catalysts
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 41 - Asymmetric reduction with oxazaborilidines
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 42 - C-C bond formations: Introduction to enolate, enamine and enol silyl ether based chemistry
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 43 - C-C bond formations using enol silyl ether and imine based chemistry including SAMP and RAMP based asymmetric alkylations
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 44 - Asymmetric C-C bond formations using Oppolzer’s camphorsultams and introduction to directed Aldol reactions
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 45 - Further aspects of Aldol chemistry including the use of boron and silicon enolates
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 46 - C-C bond formations using Evans’ oxazolidinone based chemistry
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 47 - Ireland-Claisen rearrangement: Emphasis of enolate geometry on the stereochemical outcome, and Claisen rearrangements
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 48 - Aromatic Claisen rearrangement, Johnson-Claisen rearrangement and Eschenmoser-Claisen rearrangement and synthetic
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 49 - Bellus-Claisen rearrangement, Aza-Claisen rearrangement, Thia-Claisen rearrangement, Chen-Mapp rearrangement and their synthetic applications
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 50 - Zwitterionic-Claisen rearrangement, Overmann rearrangement, Bamford- Stevens and Shapiro reactions and synthetic applications
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 51 - Introduction to allyl metal additions for C-C bond formation
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 52 - Allylindium chemistry: Mechanism, stereochemistry and synthetic applications
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 53 - Allyltin chemistry: Mechanism, stereochemistry and synthetic applications
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 54 - Chemistry of allylsilanes: Mechanism, stereochemistry and synthetic applications - Part 1
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 55 - Further synthetic aspects of the chemistry of allylsilanes - Part 2
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 56 - Further synthetic aspects of the chemistry of allylsilanes - Part 3
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 57 - Chemistry of Vinylsilanes: Mechanism, Stereochemistry and Synthetic Applications
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 58 - Peterson olefination and further synthetic aspects of vinylsilane chemistry
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 59 - Simmons Smith cyclopropanation: Mechanism, stereochemistry and synthetic applications
Link NOC:Essentials of Oxidation, Reduction and C_C Bond Formation. Application in Organic Synthesis Lecture 60 - Course Summary and Conclusion
Link NOC:Chemical Kinetics and Transition State Theory Lecture 1 - Rate: the reaction velocity
Link NOC:Chemical Kinetics and Transition State Theory Lecture 2 - Its elementary - rate law equations
Link NOC:Chemical Kinetics and Transition State Theory Lecture 3 - Arrhenius equation: what's the fuss about?
Link NOC:Chemical Kinetics and Transition State Theory Lecture 4 - Dance of atoms: from Newton to Hamilton
Link NOC:Chemical Kinetics and Transition State Theory Lecture 5 - Boltzmann distribution: a story of Hamilton, Liouville and Boltzmann
Link NOC:Chemical Kinetics and Transition State Theory Lecture 6 - Maxwell Boltzmann distribution: how fast are molecules moving?
Link NOC:Chemical Kinetics and Transition State Theory Lecture 7 - Kinetic theory of collisions: initial estimate
Link NOC:Chemical Kinetics and Transition State Theory Lecture 8 - Boltzmann distribution and kinetic theory of collisions
Link NOC:Chemical Kinetics and Transition State Theory Lecture 9 - Kinetic theory of collisions: a discussion
Link NOC:Chemical Kinetics and Transition State Theory Lecture 10 - Kinetic theory of collisions: reactive cross section
Link NOC:Chemical Kinetics and Transition State Theory Lecture 11 - Problem solving session - 1
Link NOC:Chemical Kinetics and Transition State Theory Lecture 12 - Problem solving session - 2
Link NOC:Chemical Kinetics and Transition State Theory Lecture 13 - Kinetic theory of collision and equilibrium constant
Link NOC:Chemical Kinetics and Transition State Theory Lecture 14 - Critique of kinetic theory of collisions
Link NOC:Chemical Kinetics and Transition State Theory Lecture 15 - Transition state theory and partition functions
Link NOC:Chemical Kinetics and Transition State Theory Lecture 16 - Partitioning the partition function
Link NOC:Chemical Kinetics and Transition State Theory Lecture 17 - Translating, rotating and vibrating quantum mechanically
Link NOC:Chemical Kinetics and Transition State Theory Lecture 18 - Partition function and equilibrium constant
Link NOC:Chemical Kinetics and Transition State Theory Lecture 19 - What is a transition state?
Link NOC:Chemical Kinetics and Transition State Theory Lecture 20 - A puzzle: cars on highway
Link NOC:Chemical Kinetics and Transition State Theory Lecture 21 - Transition state theory: derivation 1
Link NOC:Chemical Kinetics and Transition State Theory Lecture 22 - Practical calculation of TST rate
Link NOC:Chemical Kinetics and Transition State Theory Lecture 23 - Calculating TST rate for the reaction H+HBr
Link NOC:Chemical Kinetics and Transition State Theory Lecture 24 - Collision theory as a special case of TST
Link NOC:Chemical Kinetics and Transition State Theory Lecture 25 - TST: an intuitive proof in one dimension
Link NOC:Chemical Kinetics and Transition State Theory Lecture 26 - Rate as a flux across a dividing surface
Link NOC:Chemical Kinetics and Transition State Theory Lecture 27 - Transition state theory: derivation 2 from dynamical perspective
Link NOC:Chemical Kinetics and Transition State Theory Lecture 28 - Discussion of the assumptions of TST
Link NOC:Chemical Kinetics and Transition State Theory Lecture 29 - Thermodynamic formulation of TST
Link NOC:Chemical Kinetics and Transition State Theory Lecture 30 - Problem solving session - 3
Link NOC:Chemical Kinetics and Transition State Theory Lecture 31 - Problem solving session - 4
Link NOC:Chemical Kinetics and Transition State Theory Lecture 32 - Hills and valleys of potential energy surfaces
Link NOC:Chemical Kinetics and Transition State Theory Lecture 33 - Molecular dynamics: rolling spheres on potential energy surfaces
Link NOC:Chemical Kinetics and Transition State Theory Lecture 34 - Predictions from potential energy surfaces - rotational vs vibrational energies
Link NOC:Chemical Kinetics and Transition State Theory Lecture 35 - Free energy and potential of mean force
Link NOC:Chemical Kinetics and Transition State Theory Lecture 36 - Transmission coefficient and molecualr dynamics
Link NOC:Chemical Kinetics and Transition State Theory Lecture 37 - Problem solving session - 5
Link NOC:Chemical Kinetics and Transition State Theory Lecture 38 - Microcanonical rate constant: putting balls in jars
Link NOC:Chemical Kinetics and Transition State Theory Lecture 39 - Microcanonical rate constant: RRK model
Link NOC:Chemical Kinetics and Transition State Theory Lecture 40 - Microcanonical rate constant: magic of Marcus - RRKM model
Link NOC:Chemical Kinetics and Transition State Theory Lecture 41 - Canonical TST from micrononical RRKM model
Link NOC:Chemical Kinetics and Transition State Theory Lecture 42 - Sum and density of states
Link NOC:Chemical Kinetics and Transition State Theory Lecture 43 - Unimolecular decay - revisited
Link NOC:Chemical Kinetics and Transition State Theory Lecture 44 - Unimolecular decay: RRK's approach
Link NOC:Chemical Kinetics and Transition State Theory Lecture 45 - Unimolecular decay: RRKM's approach
Link NOC:Chemical Kinetics and Transition State Theory Lecture 46 - Problem solving session - 6
Link NOC:Concepts of Chemistry for Engineering Lecture 1 - Introduction to quantum theory
Link NOC:Concepts of Chemistry for Engineering Lecture 2 - Schrodinger's theory
Link NOC:Concepts of Chemistry for Engineering Lecture 3 - Laws of quantum mechanics
Link NOC:Concepts of Chemistry for Engineering Lecture 4 - Wave functions
Link NOC:Concepts of Chemistry for Engineering Lecture 5 - Quantum mechanics of a free particle
Link NOC:Concepts of Chemistry for Engineering Lecture 6 - Particle in 1D box
Link NOC:Concepts of Chemistry for Engineering Lecture 7 - Particle in 2D box
Link NOC:Concepts of Chemistry for Engineering Lecture 8 - Spherical polar coordinates and angular momentum
Link NOC:Concepts of Chemistry for Engineering Lecture 9 - Developing Hydrogen atom orbitals - 1
Link NOC:Concepts of Chemistry for Engineering Lecture 10 - Developing Hydrogen atom orbitals - 2
Link NOC:Concepts of Chemistry for Engineering Lecture 11 - Developing Hydrogen atom orbitals - 3
Link NOC:Concepts of Chemistry for Engineering Lecture 12 - Visualizing molecular orbitals
Link NOC:Concepts of Chemistry for Engineering Lecture 13 - Molecular orbital theory 1: Introduction
Link NOC:Concepts of Chemistry for Engineering Lecture 14 - Molecular orbital theory 2: Diatomic molecules
Link NOC:Concepts of Chemistry for Engineering Lecture 15 - Molecular orbital theory 3: Homo-diatomic molecules - I
Link NOC:Concepts of Chemistry for Engineering Lecture 16 - Molecular orbital theory 4: Homo-diatomic molecules - II
Link NOC:Concepts of Chemistry for Engineering Lecture 17 - Molecular orbital theory 5: Hetero-diatomic molecules
Link NOC:Concepts of Chemistry for Engineering Lecture 18 - Molecular orbital theory 6: Polyatomic molecules
Link NOC:Concepts of Chemistry for Engineering Lecture 19 - Molecular orbital theory 7: Ethylene (Introduction to Huckel's theory) - I
Link NOC:Concepts of Chemistry for Engineering Lecture 20 - Molecular orbital theory 8: Ethylene (Introduction to Huckel's theory) - II
Link NOC:Concepts of Chemistry for Engineering Lecture 21 - Molecular orbital theory 9: Butadiene - I
Link NOC:Concepts of Chemistry for Engineering Lecture 22 - Molecular orbital theory 9: Butadiene - II
Link NOC:Concepts of Chemistry for Engineering Lecture 23 - Concept of effective nuclear charge
Link NOC:Concepts of Chemistry for Engineering Lecture 24 - Electronic configuration of elements
Link NOC:Concepts of Chemistry for Engineering Lecture 25 - Properties of Elements (Size, IE, EA and EN)
Link NOC:Concepts of Chemistry for Engineering Lecture 26 - Polarizability
Link NOC:Concepts of Chemistry for Engineering Lecture 27 - Hard soft acid base
Link NOC:Concepts of Chemistry for Engineering Lecture 28 - Predicting molecular structures: VSEPR theory
Link NOC:Concepts of Chemistry for Engineering Lecture 29 - Coordination Chemistry: 18 electron rule and VBT
Link NOC:Concepts of Chemistry for Engineering Lecture 30 - Crystal Field Theory: Octahedral Complex
Link NOC:Concepts of Chemistry for Engineering Lecture 31 - Crystal Field Theory: Tetrahedral Complex
Link NOC:Concepts of Chemistry for Engineering Lecture 32 - Crystal Field Theory: Octahedral vs. Tetrahedral Complex
Link NOC:Concepts of Chemistry for Engineering Lecture 33 - Application of CFSE: Spinel and J-T Distortion
Link NOC:Concepts of Chemistry for Engineering Lecture 34 - Introduction to Molecular Magnetism
Link NOC:Concepts of Chemistry for Engineering Lecture 35 - Problem Solving Approach
Link NOC:Concepts of Chemistry for Engineering Lecture 36 - Magnetism
Link NOC:Concepts of Chemistry for Engineering Lecture 37 - Spectroscopic Term Symbol
Link NOC:Concepts of Chemistry for Engineering Lecture 38 - Magnetic States of Matter: Paramagnetic, Ferro and Antiferromagnetic
Link NOC:Concepts of Chemistry for Engineering Lecture 39 - Band structures of solid materials
Link NOC:Concepts of Chemistry for Engineering Lecture 40 - Density of states and doping in semiconductors
Link NOC:Concepts of Chemistry for Engineering Lecture 41 - Introduction to molecular spectroscopy
Link NOC:Concepts of Chemistry for Engineering Lecture 42 - Rotational spectroscopy
Link NOC:Concepts of Chemistry for Engineering Lecture 43 - Vibrational spectroscopy
Link NOC:Concepts of Chemistry for Engineering Lecture 44 - Electronic Spectroscopy - I
Link NOC:Concepts of Chemistry for Engineering Lecture 45 - Electronic Spectroscopy - II
Link NOC:Concepts of Chemistry for Engineering Lecture 46 - Electronic Spectroscopy - III
Link NOC:Concepts of Chemistry for Engineering Lecture 47 - Fluorescence Spectroscopy
Link NOC:Concepts of Chemistry for Engineering Lecture 48 - Fundamentals of NMR spectroscopy and MRI
Link NOC:Concepts of Chemistry for Engineering Lecture 49 - Surface characterization techniques
Link NOC:Concepts of Chemistry for Engineering Lecture 50 - Introduction to thermodynamics: Work, heat and energy
Link NOC:Concepts of Chemistry for Engineering Lecture 51 - First law of thermodynamics: Diathermic and adiabatic systems,exothermic and endothermic processes
Link NOC:Concepts of Chemistry for Engineering Lecture 52 - Enthalpy, Hess's law
Link NOC:Concepts of Chemistry for Engineering Lecture 53 - Second law of thermodynamics: Entropy and third law of thermodynamics
Link NOC:Concepts of Chemistry for Engineering Lecture 54 - Helmholtz and Gibbs free energies, Concept of spontaneity
Link NOC:Concepts of Chemistry for Engineering Lecture 55 - Electrochemical equilibrium, Nernst equation
Link NOC:Concepts of Chemistry for Engineering Lecture 56 - Acid base and solubility equilibria
Link NOC:Concepts of Chemistry for Engineering Lecture 57 - Corrosion
Link NOC:Concepts of Chemistry for Engineering Lecture 58 - Extraction of metals
Link NOC:Concepts of Chemistry for Engineering Lecture 59 - Ellingham Diagram
Link NOC:Concepts of Chemistry for Engineering Lecture 60 - Problems From Thermodynamics
Link NOC:Concepts of Chemistry for Engineering Lecture 61 - Intermolecular forces: Electrostatic and Ion-Dipole Interaction
Link NOC:Concepts of Chemistry for Engineering Lecture 62 - Intermolecular forces: Dipole-dipole, hydrogen bonding
Link NOC:Concepts of Chemistry for Engineering Lecture 63 - Real gases - Part 1
Link NOC:Concepts of Chemistry for Engineering Lecture 64 - Real gases - Part 2
Link NOC:Concepts of Chemistry for Engineering Lecture 65 - Introduction to Potential Energy Surfaces
Link NOC:Concepts of Chemistry for Engineering Lecture 66 - Potential energy surface of H3 system
Link NOC:Concepts of Chemistry for Engineering Lecture 67 - Salient features of H3 potential energy surface
Link NOC:Concepts of Chemistry for Engineering Lecture 68 - Potential Energy Surfaces of HCN and H2F system
Link NOC:Concepts of Chemistry for Engineering Lecture 69 - Representation of three dimensional structures
Link NOC:Concepts of Chemistry for Engineering Lecture 70 - Structural isomers and stereoisomers
Link NOC:Concepts of Chemistry for Engineering Lecture 71 - Configurations, Symmetry and Chirality
Link NOC:Concepts of Chemistry for Engineering Lecture 72 - Enantiomers and Diastereomers
Link NOC:Concepts of Chemistry for Engineering Lecture 73 - Optical activity, Conformational analysis, and absolute configuration
Link NOC:Concepts of Chemistry for Engineering Lecture 74 - Substitution reactions
Link NOC:Concepts of Chemistry for Engineering Lecture 75 - Elimination reactions
Link NOC:Concepts of Chemistry for Engineering Lecture 76 - Addition, Oxidation and Reduction reactions
Link NOC:Concepts of Chemistry for Engineering Lecture 77 - Synthesis of a drug molecule
Link NOC:Classics in Total Synthesis-I Lecture 1 - Overview - 1
Link NOC:Classics in Total Synthesis-I Lecture 2 - Overview - 2
Link NOC:Classics in Total Synthesis-I Lecture 3 - Overview - 3
Link NOC:Classics in Total Synthesis-I Lecture 4 - Illudin M (Kinder) Illudin C (Funk)
Link NOC:Classics in Total Synthesis-I Lecture 5 - Total Synthesis of FR900848 (Barrett)
Link NOC:Classics in Total Synthesis-I Lecture 6 - Total Synthesis of Cubane
Link NOC:Classics in Total Synthesis-I Lecture 7 - Total Synthesis of Endiandric acids
Link NOC:Classics in Total Synthesis-I Lecture 8 - Total Synthesis of Penicilin
Link NOC:Classics in Total Synthesis-I Lecture 9 - Total Synthesis of Thienamycin
Link NOC:Classics in Total Synthesis-I Lecture 10 - Total Synthesis of Prostaglandin (Corey)
Link NOC:Classics in Total Synthesis-I Lecture 11 - Total Synthesis of Prostaglandin (Johnson and Stork)
Link NOC:Classics in Total Synthesis-I Lecture 12 - Total Synthesis of Biotin and Lactacystin (i) Corey, (ii) Baldwin
Link NOC:Classics in Total Synthesis-I Lecture 13 - Total Synthesis of Triquinanes: Isocomene 1) M. Pirrung 2) Fitjer
Link NOC:Classics in Total Synthesis-I Lecture 14 - Total Synthesis of Triquinanes: Isocomene and Silphipherfol-6-en-5-one (Rawal)
Link NOC:Classics in Total Synthesis-I Lecture 15 - Total synthesis of Triquinanes by radical cyclisation - I (Curran)
Link NOC:Classics in Total Synthesis-I Lecture 16 - Total synthesis of Triquinanes by radical cyclisation - II
Link NOC:Classics in Total Synthesis-I Lecture 17 - Total synthesis of Triquinanes by photochemical reaction - I
Link NOC:Classics in Total Synthesis-I Lecture 18 - Total synthesis of Triquinanes by photochemical reaction - II
Link NOC:Classics in Total Synthesis-I Lecture 19 - Total synthesis of Triquinanes by Thermal Metathesis (Mehta)
Link NOC:Classics in Total Synthesis-I Lecture 20 - Total synthesis of Triquinanes by other reactions
Link NOC:Classics in Total Synthesis-I Lecture 21 - Total synthesis of Longifolene (Corey and Oppolzer)
Link NOC:Classics in Total Synthesis-I Lecture 22 - Total synthesis of Carpanone (Chapman)
Link NOC:Classics in Total Synthesis-I Lecture 23 - Total synthesis of Mevinolin (Clive)
Link NOC:Classics in Total Synthesis-I Lecture 24 - Total synthesis of Gibberellic Acid (Corey)
Link NOC:Classics in Total Synthesis-I Lecture 25 - Total synthesis of Gibberellic Acid (Yamada)
Link NOC:Classics in Total Synthesis-I Lecture 26 - Total synthesis of Perhydrohistrionicotoxin (Corey)
Link NOC:Classics in Total Synthesis-I Lecture 27 - Total synthesis of Strychnine (Woodward)
Link NOC:Classics in Total Synthesis-I Lecture 28 - Total synthesis of Strychnine (Rawal and Overman)
Link NOC:Classics in Total Synthesis-I Lecture 29 - Total synthesis of Strychnine (Kuehne)
Link NOC:Classics in Total Synthesis-I Lecture 30 - Total synthesis of Reserpine (Woodward)
Link NOC:Classics in Total Synthesis-I Lecture 31 - Total synthesis of Yohimbine (Tamelen and Momose)
Link NOC:Classics in Total Synthesis-I Lecture 32 - Total synthesis of Quinine (Woodward and Stork)
Link NOC:Classics in Total Synthesis-I Lecture 33 - Total synthesis of Dendrobine (Livinghouse)
Link NOC:Classics in Total Synthesis-I Lecture 34 - Total synthesis of Morphine (Gates and Overman)
Link NOC:Classics in Total Synthesis-I Lecture 35 - Total synthesis of Morphine (Parker and White)
Link NOC:Classics in Total Synthesis-I Lecture 36 - Total synthesis of Methylhomosecodaphniphyllate (Heathcock)
Link NOC:Classics in Total Synthesis-I Lecture 37 - Total synthesis of Lysergic acid (Woodward and Oppolzer)
Link NOC:Classics in Total Synthesis-I Lecture 38 - Total synthesis of Galanthamine (Barton and Kirby)
Link NOC:Classics in Total Synthesis-I Lecture 39 - Total synthesis of Epibatidine (Trost and Evans)
Link NOC:Classics in Total Synthesis-I Lecture 40 - Total synthesis of Swainsonine (Hashimoto)
Link NOC:Classics in Total Synthesis-I Lecture 41 - Total synthesis of Staurosporine (Danishefsky and Wood)
Link NOC:Classics in Total Synthesis-I Lecture 42 - Total synthesis of Manzamine A (Winkler)
Link NOC:Classics in Total Synthesis-I Lecture 43 - Total synthesis of Progesterone (Johnson)
Link NOC:Classics in Total Synthesis-I Lecture 44 - Total synthesis of Progesterone from Diosgenin (Marker)
Link NOC:Classics in Total Synthesis-I Lecture 45 - Total synthesis of Estrone (Torgov)
Link NOC:Classics in Total Synthesis-I Lecture 46 - Total synthesis of Taxol (Nicolaou)
Link NOC:Classics in Total Synthesis-I Lecture 47 - Total synthesis of Taxol (Holton)
Link NOC:Classics in Total Synthesis-I Lecture 48 - Total synthesis of Taxol (Danishefsky)
Link NOC:Classics in Total Synthesis-I Lecture 49 - Total synthesis of Taxol (Wender)
Link NOC:Classics in Total Synthesis-I Lecture 50 - Total synthesis of Eleutherobin (Nicolaou)
Link NOC:Classics in Total Synthesis-I Lecture 51 - Total synthesis of Eleutherobin (Danishefsky)
Link NOC:Classics in Total Synthesis-I Lecture 52 - Total synthesis of Phorbol (Wender)
Link NOC:Classics in Total Synthesis-I Lecture 53 - Total synthesis of Periplanone (Still and Schreiber)
Link NOC:Classics in Total Synthesis-I Lecture 54 - Total synthesis of Discodermolide (Schreiber)
Link NOC:Classics in Total Synthesis-I Lecture 55 - Total synthesis of Epothilones I (Nicolaou)
Link NOC:Classics in Total Synthesis-I Lecture 56 - Total synthesis of Epothilones II (Schinzer and Danishefsky)
Link NOC:Classics in Total Synthesis-I Lecture 57 - Total synthesis of Vineomycinone B2 (Tius and Danishefsky)
Link NOC:Classics in Total Synthesis-I Lecture 58 - Total synthesis of Zaragozic acid C (Carreira)
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 1 - CD Spectroscopy: Introduction
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 2 - Symmetry and Molecular properties
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 3 - Symmetry elements - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 4 - Symmetry elements - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 5 - Symmetry and point groups - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 6 - Symmetry and point groups - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 7 - Point group determination tutorial
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 8 - Chirality and point group - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 9 - Chirality and point group - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 10 - Chirality and point group - III tutorial
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 11 - Chirality and biology - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 12 - Chirality and biology - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 13 - Chirality and biology - III
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 14 - Chirality and biology - IV
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 15 - Chirality and biology - V
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 16 - Origin of chirality
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 17 - The physical background of chiral response - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 18 - The physical background of chiral response - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 19 - The physical background of chiral response - III
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 20 - The physical background of chiral response - IV
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 21 - The physical background of chiral response - IV
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 22 - The physical background of chiral response - V
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 23 - The physical background of chiral response - VI
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 24 - Circular Dichroism Spectra
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 25 - Examples of Circular Dichroism - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 26 - Examples of Circular Dichroism - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 27 - Examples of Circular Dichroism - III
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 28 - Examples of Circular Dichroism - IV
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 29 - Applications of CD spectroscopy - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 30 - Applications of CD spectroscopy - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 31 - Applications of CD spectroscopy - III
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 32 - Applications of CD spectroscopy - IV
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 33 - Applications of CD spectroscopy - V
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 34 - Applications of CD spectroscopy - VI
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 35 - CD spectroscopy: Conclusion
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 36 - Mössbauer Spectroscopy: Introduction
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 37 - Mössbauer Spectroscopy Fundamentals - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 38 - Mössbauer Spectroscopy
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 39 - Mössbauer Spectroscopy Fundamentals - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 40 - Mössbauer Spectroscopy Fundamentals - III
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 41 - Mössbauer Spectroscopy Fundamentals - IV
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 42 - Mössbauer Spectroscopy: Isomer shift - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 43 - Mössbauer Spectroscopy: Isomer shift - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 44 - Mössbauer Spectroscopy: Isomer shift - III
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 45 - Mössbauer Spectroscopy: Quadrupolar splitting - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 46 - Mössbauer Spectroscopy: Quadrupolar splitting - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 47 - Mössbauer Spectroscopy: Applications - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 48 - Mössbauer Spectroscopy: Applications - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 49 - Mössbauer Spectroscopy: Applications - III
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 50 - Mössbauer Spectroscopy: Data measurement
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 51 - Mössbauer Spectroscopy: Applications - IV
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 52 - Mössbauer Spectroscopy: Effect of ligands - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 53 - Mössbauer Spectroscopy: Effect of ligands - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 54 - Mössbauer Spectroscopy: Applications - V
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 55 - Mössbauer Spectroscopy: Probing ferrocenes - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 56 - Mössbauer Spectroscopy: Probing ferrocenes - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 57 - Mössbauer Spectroscopy: Probing ferrocenes - III
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 58 - Mössbauer Spectroscopy: Mixed valent complexes - I
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 59 - Mössbauer Spectroscopy: Mixed valent complexes - II
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 60 - Mössbauer Spectroscopy: Mixed valent complexes - III
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 61 - Conclusion section: CD spectroscopy
Link NOC:Circular Dichroism (CD) and Mossbauer Spectroscopy for Chemists Lecture 62 - Conclusion section: Mössbauer Spectroscopy
Link NOC:NMR Spectroscopy for Structural Biology Lecture 1 - NMR Basic Concepts - I
Link NOC:NMR Spectroscopy for Structural Biology Lecture 2 - NMR Basic Concepts - II
Link NOC:NMR Spectroscopy for Structural Biology Lecture 3 - NMR Basic Concepts - III
Link NOC:NMR Spectroscopy for Structural Biology Lecture 4 - NMR Basic Concepts - IV
Link NOC:NMR Spectroscopy for Structural Biology Lecture 5 - NMR Spectra of Molecules
Link NOC:NMR Spectroscopy for Structural Biology Lecture 6 - Chemical Shifts and Coupling constant
Link NOC:NMR Spectroscopy for Structural Biology Lecture 7 - Fine Structures in NMR Spectra
Link NOC:NMR Spectroscopy for Structural Biology Lecture 8 - Pulse Excitation and FT-NMR
Link NOC:NMR Spectroscopy for Structural Biology Lecture 9 - Practical Aspects of FT-NMR - 1
Link NOC:NMR Spectroscopy for Structural Biology Lecture 10 - Practical Aspects of FT-NMR - 2
Link NOC:NMR Spectroscopy for Structural Biology Lecture 11 - Practical Aspects of FT-NMR - 3
Link NOC:NMR Spectroscopy for Structural Biology Lecture 12 - Practical Aspects of FT-NMR - 4
Link NOC:NMR Spectroscopy for Structural Biology Lecture 13 - Polarization Transfer Technique - 1
Link NOC:NMR Spectroscopy for Structural Biology Lecture 14 - Polarization Transfer Technique - 2
Link NOC:NMR Spectroscopy for Structural Biology Lecture 15 - General Concept of Multidimensional NMR - 1
Link NOC:NMR Spectroscopy for Structural Biology Lecture 16 - General Concept of Multidimensional NMR - 2
Link NOC:NMR Spectroscopy for Structural Biology Lecture 17 - 2-D NMR or 2-D Co-relation spectroscopy : General concept - 1
Link NOC:NMR Spectroscopy for Structural Biology Lecture 18 - 2-D NMR or 2-D Co-relation spectroscopy : General concept - 2
Link NOC:NMR Spectroscopy for Structural Biology Lecture 19 - 2-D NMR or 2-D Co-relation spectroscopy : General concept - 3
Link NOC:NMR Spectroscopy for Structural Biology Lecture 20 - Introduction to NOESY and HSQC - 1
Link NOC:NMR Spectroscopy for Structural Biology Lecture 21 - Introduction to NOESY and HSQC - 2
Link NOC:NMR Spectroscopy for Structural Biology Lecture 22 - Introduction to NOESY and HSQC - 3
Link NOC:NMR Spectroscopy for Structural Biology Lecture 23 - Introduction to NOESY and HSQC - 4
Link NOC:NMR Spectroscopy for Structural Biology Lecture 24 - Application of NMR in the area of structural Biology: Structure of DNA and RNA - 1
Link NOC:NMR Spectroscopy for Structural Biology Lecture 25 - Application of NMR in the area of structural Biology: Structure of DNA and RNA - 2
Link NOC:NMR Spectroscopy for Structural Biology Lecture 26 - Application of NMR in the area of structural Biology: Structure of DNA and RNA - 3
Link NOC:NMR Spectroscopy for Structural Biology Lecture 27 - Application of NMR in the area of structural Biology: Structure of DNA and RNA - 4
Link NOC:NMR Spectroscopy for Structural Biology Lecture 28 - Application of NMR in the area of structural Biology: Structure of DNA and RNA - 5
Link NOC:NMR Spectroscopy for Structural Biology Lecture 29 - Application of NMR in the area of structural Biology: Structure of DNA and RNA - 6
Link NOC:NMR Spectroscopy for Structural Biology Lecture 30 - Application of NMR in the area of structural Biology: Structure of DNA and RNA - 7
Link NOC:NMR Spectroscopy for Structural Biology Lecture 31 - Determination of Structure and Dynamics of Proteins - 1
Link NOC:NMR Spectroscopy for Structural Biology Lecture 32 - Determination of Structure and Dynamics of Proteins - 2
Link NOC:NMR Spectroscopy for Structural Biology Lecture 33 - Determination of Structure and Dynamics of Proteins - 3
Link NOC:NMR Spectroscopy for Structural Biology Lecture 34 - Determination of Structure and Dynamics of Proteins - 4
Link NOC:NMR Spectroscopy for Structural Biology Lecture 35 - Determination of Structure and Dynamics of Proteins - 5
Link NOC:NMR Spectroscopy for Structural Biology Lecture 36 - Determination of Structure and Dynamics of Proteins - 6
Link NOC:NMR Spectroscopy for Structural Biology Lecture 37 - NMR Analysis of Protein Dynamics - I
Link NOC:NMR Spectroscopy for Structural Biology Lecture 38 - NMR Analysis of Protein Dynamics - II
Link NOC:NMR Spectroscopy for Structural Biology Lecture 39 - NMR Analysis of Protein Dynamics - III
Link NOC:NMR Spectroscopy for Structural Biology Lecture 40 - NMR Analysis of Protein Dynamics - IV
Link NOC:NMR Spectroscopy for Structural Biology Lecture 41 - Protein-Ligand and Protein-Protein Interaction
Link NOC:NMR Spectroscopy for Structural Biology Lecture 42 - NMR Analysis of Ligand specific parameters in a Protein-Ligand Interaction - I
Link NOC:NMR Spectroscopy for Structural Biology Lecture 43 - NMR Analysis of Ligand specific parameters in a Protein-Ligand Interaction - II
Link NOC:NMR Spectroscopy for Structural Biology Lecture 44 - NMR Analysis of Protein Specific Parameters in a Protein-Ligand Interaction - I
Link NOC:NMR Spectroscopy for Structural Biology Lecture 45 - NMR Analysis of Protein Specific Parameters in a Protein-Ligand Interaction - II
Link NOC:NMR Spectroscopy for Structural Biology Lecture 46 - NMR in Drug Design
Link NOC:NMR Spectroscopy for Structural Biology Lecture 47 - NMR in Drug Discovery
Link NOC:NMR Spectroscopy for Structural Biology Lecture 48 - NMR in Drug metabolism - I
Link NOC:NMR Spectroscopy for Structural Biology Lecture 49 - NMR in Drug metabolism - II
Link NOC:NMR Spectroscopy for Structural Biology Lecture 50 - NMR in Drug metabolism - III
Link NOC:NMR Spectroscopy for Structural Biology Lecture 51 - Probing Protein Dynamics by NMR Spectroscopy - I
Link NOC:NMR Spectroscopy for Structural Biology Lecture 52 - Probing Protein Dynamics by NMR Spectroscopy - II
Link NOC:NMR Spectroscopy for Structural Biology Lecture 53 - Probing Protein Dynamics by NMR Spectroscopy - III
Link NOC:NMR Spectroscopy for Structural Biology Lecture 54 - Probing Protein Dynamics by NMR Spectroscopy - IV
Link NOC:NMR Spectroscopy for Structural Biology Lecture 55 - Probing Protein Dynamics by NMR Spectroscopy - V
Link NOC:NMR Spectroscopy for Structural Biology Lecture 56 - Basics of solid state NMR spectroscopy - I
Link NOC:NMR Spectroscopy for Structural Biology Lecture 57 - Basics of solid state NMR spectroscopy - II
Link NOC:NMR Spectroscopy for Structural Biology Lecture 58 - Basics of solid state NMR spectroscopy - III
Link NOC:NMR Spectroscopy for Structural Biology Lecture 59 - Basics of solid state NMR spectroscopy - IV
Link NOC:NMR Spectroscopy for Structural Biology Lecture 60 - Basics of solid state NMR spectroscopy - V
Link NOC:Transition Metal Chemistry Lecture 1 - History of Periodic Table - 1
Link NOC:Transition Metal Chemistry Lecture 2 - History of Periodic Table - 2
Link NOC:Transition Metal Chemistry Lecture 3 - History of Periodic Table - 3
Link NOC:Transition Metal Chemistry Lecture 4 - Introduction to Transition elements - 1
Link NOC:Transition Metal Chemistry Lecture 5 - Introduction to Transition elements - 2
Link NOC:Transition Metal Chemistry Lecture 6 - Introduction to Transition elements - 3
Link NOC:Transition Metal Chemistry Lecture 7 - Introduction to Transition elements - 4
Link NOC:Transition Metal Chemistry Lecture 8 - Coordination Theory
Link NOC:Transition Metal Chemistry Lecture 9 - Wernerâs Coordination Theory
Link NOC:Transition Metal Chemistry Lecture 10 - Early Bonding Concepts
Link NOC:Transition Metal Chemistry Lecture 11 - Valence Bond Theory (VBT) - 1
Link NOC:Transition Metal Chemistry Lecture 12 - Valence Bond Theory (VBT) - 2
Link NOC:Transition Metal Chemistry Lecture 13 - Background To Crystal Field Theory (CFT)
Link NOC:Transition Metal Chemistry Lecture 14 - Crystal Field Theory (CFT) Jahn-Teller Theorem
Link NOC:Transition Metal Chemistry Lecture 15 - Crystal Field Theory (CFT) - 1
Link NOC:Transition Metal Chemistry Lecture 16 - Crystal Field Theory (CFT) - 2
Link NOC:Transition Metal Chemistry Lecture 17 - Ligand Field Theory (LFT) - 1
Link NOC:Transition Metal Chemistry Lecture 18 - Ligand Field Theory (LFT) - 2
Link NOC:Transition Metal Chemistry Lecture 19 - Ligand Field Theory (LFT) - 3
Link NOC:Transition Metal Chemistry Lecture 20 - Ligand Field Theory (LFT) - 4
Link NOC:Transition Metal Chemistry Lecture 21 - 18 Electron Rule
Link NOC:Transition Metal Chemistry Lecture 22 - 18 Electron Rule
Link NOC:Transition Metal Chemistry Lecture 23 - Metalâ Metal Multiple Bonds
Link NOC:Transition Metal Chemistry Lecture 24 - Metalâ Metal Multiple Bonds [Quadruple and Quintuple Bonding]
Link NOC:Transition Metal Chemistry Lecture 25 - Preparation of metal Complexes
Link NOC:Transition Metal Chemistry Lecture 26 - Preparation of metal Complexes
Link NOC:Transition Metal Chemistry Lecture 27 - Classification of ligands by donor atoms
Link NOC:Transition Metal Chemistry Lecture 28 - Classification of ligands by donor atoms - Hydrogen
Link NOC:Transition Metal Chemistry Lecture 29 - Classification of ligands by donor atoms - Carbon - 1
Link NOC:Transition Metal Chemistry Lecture 30 - Classification of ligands by donor atoms - Carbon - 2
Link NOC:Transition Metal Chemistry Lecture 31 - Classification of ligands by donor atoms - Carbon - 3
Link NOC:Transition Metal Chemistry Lecture 32 - Classification of ligands by donor atoms - Carbon - 4
Link NOC:Transition Metal Chemistry Lecture 33 - Classification of ligands by donor atoms - Nitrogen - 1
Link NOC:Transition Metal Chemistry Lecture 34 - Classification of ligands by donor atoms - Nitrogen - 2
Link NOC:Transition Metal Chemistry Lecture 35 - Classification of ligands by donor atoms - Nitrogen - 3
Link NOC:Transition Metal Chemistry Lecture 36 - Classification of ligands by donor atoms - Oxygen, Phosphorus
Link NOC:Transition Metal Chemistry Lecture 37 - Classification of ligands by donor atoms - Phosphorus - 1
Link NOC:Transition Metal Chemistry Lecture 38 - Classification of ligands by donor atoms - Phosphorus - 2
Link NOC:Transition Metal Chemistry Lecture 39 - Classification of ligands by donor atoms - Phosphorus - 3
Link NOC:Transition Metal Chemistry Lecture 40 - Classification of ligands by donor atoms - Halogens
Link NOC:Transition Metal Chemistry Lecture 41 - Oxidative addition and reductive elimination reactions - 1
Link NOC:Transition Metal Chemistry Lecture 42 - Oxidative addition and reductive elimination reactions - 2
Link NOC:Transition Metal Chemistry Lecture 43 - Oxidative addition and reductive elimination reactions - 3
Link NOC:Transition Metal Chemistry Lecture 44 - Oxidative addition and reductive elimination reactions - 4
Link NOC:Transition Metal Chemistry Lecture 45 - Inorganic Reaction Mechanisms
Link NOC:Transition Metal Chemistry Lecture 46 - Inorganic Reaction Mechanisms Square planar complexes
Link NOC:Transition Metal Chemistry Lecture 47 - Trans-Effect
Link NOC:Transition Metal Chemistry Lecture 48 - Substitution Reactions in Square Planar Complexes, Trans-Effect
Link NOC:Transition Metal Chemistry Lecture 49 - Substitution Reactions in Octahedral Complexes
Link NOC:Transition Metal Chemistry Lecture 50 - Substitution Reactions in Octahedral Complexes; Stereochemistry of Products
Link NOC:Transition Metal Chemistry Lecture 51 - Electron-Transfer Processes
Link NOC:Transition Metal Chemistry Lecture 52 - Electron-Transfer Processes
Link NOC:Transition Metal Chemistry Lecture 53 - Methods of Characterization UV-Visible Spectroscopy
Link NOC:Transition Metal Chemistry Lecture 54 - Methods of Characterization UV-Visible Spectroscopy
Link NOC:Transition Metal Chemistry Lecture 55 - UV-Visible Spectroscopy
Link NOC:Transition Metal Chemistry Lecture 56 - UV-Visible Spectroscopy
Link NOC:Transition Metal Chemistry Lecture 57 - NMR Spectroscopy
Link NOC:Transition Metal Chemistry Lecture 58 - NMR Spectroscopy
Link NOC:Transition Metal Chemistry Lecture 59 - NMR and IR Spectroscopy
Link NOC:Transition Metal Chemistry Lecture 60 - Summary and Conclusion
Link NOC:Nuclear and Radiochemistry Lecture 1 - Radioactivity
Link NOC:Nuclear and Radiochemistry Lecture 2 - Radioactive decay
Link NOC:Nuclear and Radiochemistry Lecture 3 - Radioactive decay chain
Link NOC:Nuclear and Radiochemistry Lecture 4 - Radioactive equilibria
Link NOC:Nuclear and Radiochemistry Lecture 5 - Nuclear structure and stability
Link NOC:Nuclear and Radiochemistry Lecture 6 - Nuclear force and nuclear properties
Link NOC:Nuclear and Radiochemistry Lecture 7 - Liquid drop model
Link NOC:Nuclear and Radiochemistry Lecture 8 - Applications of Liquid drop model
Link NOC:Nuclear and Radiochemistry Lecture 9 - Nuclear Shell model
Link NOC:Nuclear and Radiochemistry Lecture 10
Link NOC:Nuclear and Radiochemistry Lecture 11 - Alpha decay
Link NOC:Nuclear and Radiochemistry Lecture 12 - Beta decay
Link NOC:Nuclear and Radiochemistry Lecture 13 - Gamma decay
Link NOC:Nuclear and Radiochemistry Lecture 14 - Interaction of radiations with matter
Link NOC:Nuclear and Radiochemistry Lecture 15 - Interaction of fast electrons with matter
Link NOC:Nuclear and Radiochemistry Lecture 16 - Interaction of electromegnetic radiations with matter
Link NOC:Nuclear and Radiochemistry Lecture 17 - Principles of radiation detectors
Link NOC:Nuclear and Radiochemistry Lecture 18 - Gas filled detectors
Link NOC:Nuclear and Radiochemistry Lecture 19 - Scintillator detectors
Link NOC:Nuclear and Radiochemistry Lecture 20 - Semiconductor detectors
Link NOC:Nuclear and Radiochemistry Lecture 21
Link NOC:Nuclear and Radiochemistry Lecture 22
Link NOC:Nuclear and Radiochemistry Lecture 23
Link NOC:Nuclear and Radiochemistry Lecture 24
Link NOC:Nuclear and Radiochemistry Lecture 25
Link NOC:Nuclear and Radiochemistry Lecture 26 - Compound nucleus reactions
Link NOC:Nuclear and Radiochemistry Lecture 27 - Nuclear fission
Link NOC:Nuclear and Radiochemistry Lecture 28 - Nuclear fusion
Link NOC:Nuclear and Radiochemistry Lecture 29 - Production of radioisotopes using neutrons
Link NOC:Nuclear and Radiochemistry Lecture 30 - Radioisotope production using charged particles
Link NOC:Nuclear and Radiochemistry Lecture 31 - Radiochemical practices
Link NOC:Nuclear and Radiochemistry Lecture 32 - Radioanalytical techniques and applications
Link NOC:Nuclear and Radiochemistry Lecture 33 - Nuclear analytical techniques
Link NOC:Nuclear and Radiochemistry Lecture 34 - Applications of neutron activation analysis
Link NOC:Nuclear and Radiochemistry Lecture 35 - Ion beam analysis
Link NOC:Nuclear and Radiochemistry Lecture 36 - Nuclear reaction analysis and particle induced gamma emission
Link NOC:Nuclear and Radiochemistry Lecture 37 - Nuclear Probes: Positron annihilation spectroscopy
Link NOC:Nuclear and Radiochemistry Lecture 38 - Perturbed angular corelation
Link NOC:Nuclear and Radiochemistry Lecture 39 - Radioisotope applications in healthcare
Link NOC:Nuclear and Radiochemistry Lecture 40 - Radioisotope applications in Industry, agriculture and food technology
Link NOC:Nuclear and Radiochemistry Lecture 41 - History of actinides
Link NOC:Nuclear and Radiochemistry Lecture 42 - Actinide concept
Link NOC:Nuclear and Radiochemistry Lecture 43 - Actinide ionic species in water
Link NOC:Nuclear and Radiochemistry Lecture 44 - Actinide hydration and Hydrolysis
Link NOC:Nuclear and Radiochemistry Lecture 45 - pH-pE concept
Link NOC:Nuclear and Radiochemistry Lecture 46 - Ln/An absorption spectroscopy - I
Link NOC:Nuclear and Radiochemistry Lecture 47 - Ln/An absorption spectroscopy - II
Link NOC:Nuclear and Radiochemistry Lecture 48 - Ln/An emission spectroscopy - I
Link NOC:Nuclear and Radiochemistry Lecture 49 - Ln/An emission spectroscopy - II
Link NOC:Nuclear and Radiochemistry Lecture 50 - Solution chemistry Actinides
Link NOC:Nuclear and Radiochemistry Lecture 51 - Complexation of actinides - I
Link NOC:Nuclear and Radiochemistry Lecture 52 - Complexation of actinides - II
Link NOC:Nuclear and Radiochemistry Lecture 53 - Solvent extraction of actinides - I
Link NOC:Nuclear and Radiochemistry Lecture 54 - Solvent extraction of actinides - II
Link NOC:Nuclear and Radiochemistry Lecture 55 - Actinide partitioning
Link NOC:Nuclear and Radiochemistry Lecture 56 - Analytical chemistry of actinides
Link NOC:Nuclear and Radiochemistry Lecture 57 - Transactinides
Link NOC:Nuclear and Radiochemistry Lecture 58 - Fast radiochemical separations
Link NOC:Nuclear and Radiochemistry Lecture 59 - Actinides in the environment
Link NOC:Nuclear and Radiochemistry Lecture 60 - Actinides sorption and migration
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 1 - General introduction to Statistical Thermodynamics
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 2 - Configuration and Weights
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 3 - Configuration and Weights (Continued...)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 4 - Boltzmann Distribution
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 5 - The Molecular Partition Function
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 6 - The Molecular Partition Function of a uniform ladder of energy levels
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 7 - The partition function for a particle of mass m free to move in a 1D container
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 8 - The partition function for a particle of mass m free to move in a 3D container
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 9 - Numerical Problems Set-I (based on partition function)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 10 - Numerical Problems Set-II
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 11 - The Internal Energy
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 12 - Obtaining expression for beta
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 13 - The Statistical Entropy
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 14 - Connecting partition function with entropy
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 15 - Solving numerical problems based on Internal energy and Entropy
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 16 - Solving numerical problems based on Internal energy and Entropy
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 17 - Negative Temperature
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 18 - Further discussion on q (Partition function), U (Internal energy) and S (Entropy)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 19 - The Canonical Partition Function
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 20 - Relating Canonical Partition Function Internal Energy and Entropy
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 21 - Recovering molecular partition function q from canonical partition function Q
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 22 - Entropy of a monatomic gas
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 23 - Further discussion on entropy of a monatomic gas - I
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 24 - Further discussion on entropy of a monatomic gas - II
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 25 - The Thermodynamic Functions (Pressure)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 26 - The Thermodynamic Functions (Enthalpy)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 27 - The Thermodynamic Functions (The Gibbs Energy)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 28 - The Thermodynamic Functions (The Molecular Partition Function)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 29 - The Rotational Contribution to Molecular Partition Function
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 30 - The Rotational Contribution to Molecular Partition Function (Nonlinear Rotor)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 31 - The Rotational Contribution to Molecular Partition Function
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 32 - Rotational Partition Function
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 33 - Vibrational Partition Function - I
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 34 - Vibrational Partition Function - II
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 35 - Vibrational Partition Function - Applications
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 36 - Electronic Partition Function
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 37 - Mean Energies
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 38 - Mean Energies (Continued...)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 39 - Heat Capacity
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 40 - Heat Capacity (Continued...)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 41 - Mean Energies (Applications)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 42 - Problem Solving
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 43 - Residual Entropy
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 44 - Residual Entropy (Continued...)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 45 - Relation between equilibrium constant K and partition function q
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 46 - Relation between equilibrium constant K and partition function q (Continued...)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 47 - Relation between equilibrium constant K and partition function q (Applications-1)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 48 - Relation between equilibrium constant K and partition function q (Applications-2)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 49 - Contributions to equilibrium constant
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 50 - Contributions to equilibrium constant (Continued...)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 51 - Contributions to equilibrium constant (Continued...) and Problems Solving
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 52 - Problem Solving
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 53 - Problem Solving (Continued...)
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 54 - Equations of state
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 55 - Bose-Einstein Statistics
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 56 - Problem Solving
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 57 - FERMI-DIRAC Statistics
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 58 - Radial Distribution Function
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 59 - Recap - 1
Link NOC:Fundamentals of Statistical Thermodynamics Lecture 60 - Recap - 2
Link NOC:Interpretative Molecular Spectroscopy Lecture 1 - Various Analytical Techniques and their applications
Link NOC:Interpretative Molecular Spectroscopy Lecture 2 - Introduction to 1H NMR Spectroscopy
Link NOC:Interpretative Molecular Spectroscopy Lecture 3 - NMR signals and magnetic shielding
Link NOC:Interpretative Molecular Spectroscopy Lecture 4 - Introduction to the concept of Chemical Shifts in NMR spectra
Link NOC:Interpretative Molecular Spectroscopy Lecture 5 - Chemical Shifts for different type of protons
Link NOC:Interpretative Molecular Spectroscopy Lecture 6 - N+1 Rule and Pascal's Triangle
Link NOC:Interpretative Molecular Spectroscopy Lecture 7 - Coupling constants for different types of molecules
Link NOC:Interpretative Molecular Spectroscopy Lecture 8 - Second Order Coupling
Link NOC:Interpretative Molecular Spectroscopy Lecture 9 - Introduction to 13C NMR Spectroscopy
Link NOC:Interpretative Molecular Spectroscopy Lecture 10 - Introduction to 31P NMR Spectroscopy
Link NOC:Interpretative Molecular Spectroscopy Lecture 11 - Chemical Shift Range in 31P NMR Spectroscopy
Link NOC:Interpretative Molecular Spectroscopy Lecture 12 - Examples explaining Multinuclear NMR Spectroscopy - 1
Link NOC:Interpretative Molecular Spectroscopy Lecture 13 - Examples explaining Multinuclear NMR Spectroscopy - 2
Link NOC:Interpretative Molecular Spectroscopy Lecture 14 - Examples explaining Multinuclear NMR Spectroscopy - 3
Link NOC:Interpretative Molecular Spectroscopy Lecture 15 - Examples explaining Multinuclear NMR Spectroscopy - 4
Link NOC:Interpretative Molecular Spectroscopy Lecture 16 - Examples explaining Multinuclear NMR Spectroscopy - 5
Link NOC:Interpretative Molecular Spectroscopy Lecture 17 - Monitoring reaction through 31P NMR Spectroscopy
Link NOC:Interpretative Molecular Spectroscopy Lecture 18 - 19F, 14N and 15N NMR Spectroscopy
Link NOC:Interpretative Molecular Spectroscopy Lecture 19 - 6Li and 7Li NMR Spectroscopy
Link NOC:Interpretative Molecular Spectroscopy Lecture 20 - 11B, 10B and 199Hg NMR Spectroscopy
Link NOC:Interpretative Molecular Spectroscopy Lecture 21 - Introduction to UV Spectroscopy
Link NOC:Interpretative Molecular Spectroscopy Lecture 22 - Types of Electronic Transitions and Woodward-Fieser Rules
Link NOC:Interpretative Molecular Spectroscopy Lecture 23 - Spin Orbit Coupling and Term Symbols
Link NOC:Interpretative Molecular Spectroscopy Lecture 24 - Ground State Term Symbol
Link NOC:Interpretative Molecular Spectroscopy Lecture 25 - Calculating microstates for different electronic configuration
Link NOC:Interpretative Molecular Spectroscopy Lecture 26 - Selection Rule of Electronic Transition
Link NOC:Interpretative Molecular Spectroscopy Lecture 27 - Orgel Level Diagrams
Link NOC:Interpretative Molecular Spectroscopy Lecture 28 - Racah Parameters and Tanabe-Sugano Diagrams
Link NOC:Interpretative Molecular Spectroscopy Lecture 29 - Introduction to IR Spectroscopy - 1
Link NOC:Interpretative Molecular Spectroscopy Lecture 30 - Introduction to IR Spectroscopy - 2
Link NOC:Interpretative Molecular Spectroscopy Lecture 31 - Interpretation of IR Spectra
Link NOC:Interpretative Molecular Spectroscopy Lecture 32 - IR stretching frequencies for various functional groups
Link NOC:Interpretative Molecular Spectroscopy Lecture 33 - Hook's Law - Numericals
Link NOC:Interpretative Molecular Spectroscopy Lecture 34 - IR Spectra of carbonyl compounds - 1
Link NOC:Interpretative Molecular Spectroscopy Lecture 35 - IR Spectra of carbonyl compounds - 2
Link NOC:Interpretative Molecular Spectroscopy Lecture 36 - Numerical Problems related to IR Spectroscopy - 1
Link NOC:Interpretative Molecular Spectroscopy Lecture 37 - Numerical Problems related to IR Spectroscopy - 2
Link NOC:Interpretative Molecular Spectroscopy Lecture 38 - Introduction to Mass Spectrometry
Link NOC:Interpretative Molecular Spectroscopy Lecture 39 - Isotope Peaks in Mass Spectrometry
Link NOC:Interpretative Molecular Spectroscopy Lecture 40 - Hydrogen deficiency Index
Link NOC:Interpretative Molecular Spectroscopy Lecture 41 - EI Mass Spectra of various molecules - 1
Link NOC:Interpretative Molecular Spectroscopy Lecture 42 - EI Mass Spectra of various molecules - 2
Link NOC:Interpretative Molecular Spectroscopy Lecture 43 - EI Mass Spectra of various molecules - 3
Link NOC:Interpretative Molecular Spectroscopy Lecture 44 - Types of Mass Spectrometry
Link NOC:Interpretative Molecular Spectroscopy Lecture 45 - Introduction to EPR Spectroscopy - 1
Link NOC:Interpretative Molecular Spectroscopy Lecture 46 - Introduction to EPR Spectroscopy - 2
Link NOC:Interpretative Molecular Spectroscopy Lecture 47 - Hyperfine Interactions
Link NOC:Interpretative Molecular Spectroscopy Lecture 48 - Examples of Hyperfine Interactions
Link NOC:Interpretative Molecular Spectroscopy Lecture 49 - Introduction to Mössbauer Spectroscopy (Mös)
Link NOC:Interpretative Molecular Spectroscopy Lecture 50 - More discussion, problems and solutions (Mös)
Link NOC:Interpretative Molecular Spectroscopy Lecture 51 - Problems and Solutions - 1
Link NOC:Interpretative Molecular Spectroscopy Lecture 52 - Problems and Solutions - 2
Link NOC:Interpretative Molecular Spectroscopy Lecture 53 - Problems and Solutions - 3
Link NOC:Interpretative Molecular Spectroscopy Lecture 54 - Problems and Solutions - 4
Link NOC:Interpretative Molecular Spectroscopy Lecture 55 - Problems and Solutions - 5
Link NOC:Interpretative Molecular Spectroscopy Lecture 56 - Rule of Thirteen and Nitrogen Rule
Link NOC:Interpretative Molecular Spectroscopy Lecture 57 - Problems and Solutions - 6
Link NOC:Interpretative Molecular Spectroscopy Lecture 58 - Problems and Solutions - 7
Link NOC:Interpretative Molecular Spectroscopy Lecture 59 - Problems and Solutions - 8
Link NOC:Interpretative Molecular Spectroscopy Lecture 60 - Summary and conclusion
Link NOC:Many Body Methods in Quantum Chemistry Lecture 1 - Failure of classical mechanics
Link NOC:Many Body Methods in Quantum Chemistry Lecture 2 - Postulates of quantum mechanics
Link NOC:Many Body Methods in Quantum Chemistry Lecture 3 - Postulate 5 and 6
Link NOC:Many Body Methods in Quantum Chemistry Lecture 4 - Overview of exactly solvable system
Link NOC:Many Body Methods in Quantum Chemistry Lecture 5 - Introduction to many electron problem
Link NOC:Many Body Methods in Quantum Chemistry Lecture 6 - Non-interacting and interacting quantum particles
Link NOC:Many Body Methods in Quantum Chemistry Lecture 7 - Spin orbital concept
Link NOC:Many Body Methods in Quantum Chemistry Lecture 8 - Slater determinant introduction
Link NOC:Many Body Methods in Quantum Chemistry Lecture 9 - Form of exact wave function for interacting particles
Link NOC:Many Body Methods in Quantum Chemistry Lecture 10 - A brief introduction to Configuration Interaction (CI)
Link NOC:Many Body Methods in Quantum Chemistry Lecture 11 - Variational method and Rayleigh-Ritz variation
Link NOC:Many Body Methods in Quantum Chemistry Lecture 12 - Linear variation method
Link NOC:Many Body Methods in Quantum Chemistry Lecture 13 - Hartree-Fock theory introduction
Link NOC:Many Body Methods in Quantum Chemistry Lecture 14 - Slater rules for matrix elements
Link NOC:Many Body Methods in Quantum Chemistry Lecture 15 - Spin integrated for closed shell determinant
Link NOC:Many Body Methods in Quantum Chemistry Lecture 16 - Examples of spin integrated determinants
Link NOC:Many Body Methods in Quantum Chemistry Lecture 17 - Introduction to Lagrange variation
Link NOC:Many Body Methods in Quantum Chemistry Lecture 18 - General lagrange variation
Link NOC:Many Body Methods in Quantum Chemistry Lecture 19 - Lagrange variation to minimize the the Hartree-Fock energy
Link NOC:Many Body Methods in Quantum Chemistry Lecture 20 - Non-canonical HF equation
Link NOC:Many Body Methods in Quantum Chemistry Lecture 21 - Interpretation of coulomb and exchange terms
Link NOC:Many Body Methods in Quantum Chemistry Lecture 22 - Unitary transformation of non-canonical HF equation
Link NOC:Many Body Methods in Quantum Chemistry Lecture 23 - Canonical Hartree-Fock equation
Link NOC:Many Body Methods in Quantum Chemistry Lecture 24 - Koopmans' approximation for IP
Link NOC:Many Body Methods in Quantum Chemistry Lecture 25 - Koopmans' approximation for EA
Link NOC:Many Body Methods in Quantum Chemistry Lecture 26 - Spin integrated Hartree-Fock for closed shell system (RHF)
Link NOC:Many Body Methods in Quantum Chemistry Lecture 27 - Molecular Hartree-Fock introduction
Link NOC:Many Body Methods in Quantum Chemistry Lecture 28 - Hartree-Fock Rothaan Hall equation
Link NOC:Many Body Methods in Quantum Chemistry Lecture 29 - Symmetry of two electron integrals
Link NOC:Many Body Methods in Quantum Chemistry Lecture 30 - HF Roothan equation in terms of atomic orbitals
Link NOC:Many Body Methods in Quantum Chemistry Lecture 31 - Koopmans' IP for molecules
Link NOC:Many Body Methods in Quantum Chemistry Lecture 32 - Koopmans' EA for molecules
Link NOC:Many Body Methods in Quantum Chemistry Lecture 33 - Roothaan equation in orthonormalized basis
Link NOC:Many Body Methods in Quantum Chemistry Lecture 34 - Review of Hartree-Fock theory
Link NOC:Many Body Methods in Quantum Chemistry Lecture 35 - Charge density, Bond order and Population analysis
Link NOC:Many Body Methods in Quantum Chemistry Lecture 36 - Dipole Moment
Link NOC:Many Body Methods in Quantum Chemistry Lecture 37 - Introduction to basis set
Link NOC:Many Body Methods in Quantum Chemistry Lecture 38 - Dunning and Pople basis set
Link NOC:Many Body Methods in Quantum Chemistry Lecture 39 - Polarization and diffuse function
Link NOC:Many Body Methods in Quantum Chemistry Lecture 40 - Brillouin's theorem and Slater's rule type-2
Link NOC:Many Body Methods in Quantum Chemistry Lecture 41 - Slater rule type-2
Link NOC:Many Body Methods in Quantum Chemistry Lecture 42 - Spin adapted determinant
Link NOC:Many Body Methods in Quantum Chemistry Lecture 43 - Dissociation of Hydrogen molecule problem
Link NOC:Many Body Methods in Quantum Chemistry Lecture 44 - Inadequacies of restricted Hartree-Fock theory
Link NOC:Many Body Methods in Quantum Chemistry Lecture 45 - Hartree-Fock perturbation theory and correlation correction
Link NOC:Many Body Methods in Quantum Chemistry Lecture 46 - Hartree-Fock perturbation theory (Continued...)
Link NOC:Many Body Methods in Quantum Chemistry Lecture 47 - Introduction of 2nd order perturbation theory
Link NOC:Many Body Methods in Quantum Chemistry Lecture 48 - Intermediate normalization and an expression for the Correlation energy
Link NOC:Many Body Methods in Quantum Chemistry Lecture 49 - Slater rule -3 and derivation of 2-nd order perturbation energy
Link NOC:Many Body Methods in Quantum Chemistry Lecture 50 - Physical insight of pair correlation theory
Link NOC:Many Body Methods in Quantum Chemistry Lecture 51 - Introduction to configuration intercation (CI)
Link NOC:Many Body Methods in Quantum Chemistry Lecture 52 - Determine the parameter of CI
Link NOC:Many Body Methods in Quantum Chemistry Lecture 53 - Construction of CIS hamiltonian matrix
Link NOC:Many Body Methods in Quantum Chemistry Lecture 54 - Importance of doubly excited determinants in correlation contribution
Link NOC:Many Body Methods in Quantum Chemistry Lecture 55 - Intermediate normalization and an expression for the Correlation energy
Link NOC:Many Body Methods in Quantum Chemistry Lecture 56 - CI equation in terms of Normal-Ordered hamiltonian
Link NOC:Many Body Methods in Quantum Chemistry Lecture 57 - Doubly excited CI function (D-CI)
Link NOC:Many Body Methods in Quantum Chemistry Lecture 58 - Matrix structure of CISD (singly and doubly excited CI)
Link NOC:Many Body Methods in Quantum Chemistry Lecture 59 - Some illustrative example
Link NOC:Many Body Methods in Quantum Chemistry Lecture 60 - Effects of singly excited determinant in the calculation
Link NOC:Many Body Methods in Quantum Chemistry Lecture 61 - D-CI for non-interacting hydrogen molecules
Link NOC:Many Body Methods in Quantum Chemistry Lecture 62 - Size consistency problem in truncated CI
Link NOC:Many Body Methods in Quantum Chemistry Lecture 63 - N-dependence of D-CI correlation energy
Link NOC:Many Body Methods in Quantum Chemistry Lecture 64 - problem of truncating CI
Link NOC:Many Body Methods in Quantum Chemistry Lecture 65 - Introduction of second quantization operator in quantum mechanics
Link NOC:Many Body Methods in Quantum Chemistry Lecture 66 - Creation and annihilation operator and their properties
Link NOC:Many Body Methods in Quantum Chemistry Lecture 67 - Operators in second quantization
Link NOC:Many Body Methods in Quantum Chemistry Lecture 68 - Some basic examples related with second quantization operator
Link NOC:Many Body Methods in Quantum Chemistry Lecture 69 - Hole-Particle formalism
Link NOC:Many Body Methods in Quantum Chemistry Lecture 70 - Hugenholtz rule for diagrammatic construction of MP perturbation theory
Link NOC:Many Body Methods in Quantum Chemistry Lecture 71 - Linked cluster diagram
Link NOC:Many Body Methods in Quantum Chemistry Lecture 72 - Energy expression for higher order Moller-Plasset perturbation theory
Link NOC:Many Body Methods in Quantum Chemistry Lecture 73 - Diagrammatic representation of MP3 energy and some practice problem
Link NOC:Many Body Methods in Quantum Chemistry Lecture 74 - Overview of the some other correlation calculation method
Link NOC:Many Body Methods in Quantum Chemistry Lecture 75 - A brief introduction to Coupled cluster theory
Link Bio-Physical Chemistry Lecture 1 - A Course on Bio-physical Chemistry
Link Bio-Physical Chemistry Lecture 2 - Protein Structure
Link Bio-Physical Chemistry Lecture 3 - Secondary Structure of Proteins
Link Bio-Physical Chemistry Lecture 4 - Secondary Structure of Proteins (Continued...)
Link Bio-Physical Chemistry Lecture 5 - Tertiary Structure
Link Bio-Physical Chemistry Lecture 6 - Forces in Protein Folding
Link Bio-Physical Chemistry Lecture 7 - Forces in Protein Folding (Continued...)
Link Bio-Physical Chemistry Lecture 8 - Electrostatics (Continued...)
Link Bio-Physical Chemistry Lecture 9 - Intermolecular Interactions
Link Bio-Physical Chemistry Lecture 10 - Dipole-Dipole Interaction
Link Bio-Physical Chemistry Lecture 11 - Electrostatics (Continued...)
Link Bio-Physical Chemistry Lecture 12 - Hydrophobic Effect
Link Bio-Physical Chemistry Lecture 13 - Hydrophobic Effect (Continued...)
Link Bio-Physical Chemistry Lecture 14 - Hydrogen Bonding
Link Bio-Physical Chemistry Lecture 15 - Protein Stability Curves
Link Bio-Physical Chemistry Lecture 16 - Thermodynamics of Protein Unfolding
Link Bio-Physical Chemistry Lecture 17 - Thermodynamics of Protein Unfolding (Continued...)
Link Bio-Physical Chemistry Lecture 18 - Mechanism of Chemical Denaturation
Link Bio-Physical Chemistry Lecture 19 - Pressure Induced Denaturation (The P-T Diagram)
Link Bio-Physical Chemistry Lecture 20 - Protein Folding Pathways and Energy Landscapes
Link Bio-Physical Chemistry Lecture 21 - Diffusion
Link Bio-Physical Chemistry Lecture 22 - Diffusion (Continued...)
Link Bio-Physical Chemistry Lecture 23 - Diffusion (Continued...)
Link Bio-Physical Chemistry Lecture 24 - Langevin Equation and Brownian Motion
Link Bio-Physical Chemistry Lecture 25 - Langevin Equation and Brownian Motion (Continued...)
Link Bio-Physical Chemistry Lecture 26 - Langevin Equation and Brownian Motion (Continued...)
Link Bio-Physical Chemistry Lecture 27 - Protein Folding : Mechanisms and Kinetics
Link Bio-Physical Chemistry Lecture 28 - Protein Folding : Mechanisms and Kinetics (Continued...)
Link Bio-Physical Chemistry Lecture 29 - Protein Folding : Mechanisms and Kinetics (Continued...)
Link Bio-Physical Chemistry Lecture 30 - Protein Folding : The Chevron-Plot
Link Bio-Physical Chemistry Lecture 31 - Protein Folding Kinetics : Rapid Mixing and Relaxation Techniques
Link Bio-Physical Chemistry Lecture 32 - Protein Folding Kinetics : Rapid Mixing and Relaxation Techniques (Continued...)
Link Bio-Physical Chemistry Lecture 33 - Protein Folding Kinetics : Rapid Mixing and Relaxation Techniques (Continued...)
Link Bio-Physical Chemistry Lecture 34 - Protein Folding Kinetics : Rapid Mixing and Relaxation Techniques (Continued...)
Link Bio-Physical Chemistry Lecture 35 - Experimental Tools
Link Bio-Physical Chemistry Lecture 36 - Spectroscopy : The Franck Condon Principle
Link Bio-Physical Chemistry Lecture 37 - Spectroscopy : The Franck Condon Principle (Continued...)
Link Bio-Physical Chemistry Lecture 38 - Electronic Spectroscopy Absorption and Fluorescence
Link Bio-Physical Chemistry Lecture 39 - Fluorescence
Link Bio-Physical Chemistry Lecture 40 - Fluorescence Quenching
Link Bio-Physical Chemistry Lecture 41 - Infrared Spectroscopy of Proteins
Link Bio-Physical Chemistry Lecture 42 - Infrared Spectroscopy of Proteins (Continued...)
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 1 - Introduction to Spectroscopy - I
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 2 - Introduction to Spectroscopy - II
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 3 - Introduction to Spectroscopy - III
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 4 - Introduction to Spectroscopy - IV
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 5 - Introduction to Spectroscopy - V
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 6 - Introduction to Spectroscopy - VI
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 7 - Rotational, rotational Raman Spectroscopy theory and Application - I
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 8 - Rotational, rotational Raman Spectroscopy theory and Application - II
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 9 - Vibrational Spectroscopy Theory and Application - I
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 10 - Vibrational, Rotational-Vibrational, Raman Spectroscopy - II
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 11 - Vibrational, Rotational-Vibrational, Raman Spectroscopy - III
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 12 - Problems on Rotational, Vibrational and Raman Spectroscopy
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 13 - Atomic Spectroscopy - I
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 14 - Atomic Spectroscopy - II
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 15 - Atomic Spectroscopy - III
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 16 - Atomic Spectroscopy - IV
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 17 - Atomic and Molecular Spectroscopy
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 18 - Electronic Spectra of Diatomic Molecules and UV-Vis Spectroscopy
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 19 - UV-Visible Spectroscopy of Conjugated Molecules
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 20 - UV-Vis Spectroscopy and its Applications - I
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 21 - UV-Vis Spectroscopy and its Applications - II
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 22 - UV-Vis and Fluorescence Spectroscopy
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 23 - Fluorescence Spectroscopy (Continued...)
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 24 - Application of Fluorescence Spectroscopy
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 25 - Application of Steady-State Fluorescence
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 26 - Time- resolved Fluorescence Spectroscopy
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 27 - Microscopy
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 28 - Contrast in Microscopy, Fluorescence Microscopy
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 29 - Fluorescence Microscopy and Application
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 30 - Principle of NMR
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 31 - NMR data processing and Chemical shift
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 32 - Structure Informations from NMR
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 33 - Structure Calculation and 2D-NMR Spectroscopy
Link NOC:Spectroscopic Techniques for Pharmaceutical and Biopharmaceutical Industries Lecture 34 - Mass Spectroscopy
Link NOC:Introductory Non-Linear Dynamics Lecture 1 - Introduction, Stability, Phase Space and Invariant Sets - 1
Link NOC:Introductory Non-Linear Dynamics Lecture 2 - Introduction, Stability, Phase Space and Invariant Sets - 2
Link NOC:Introductory Non-Linear Dynamics Lecture 3 - Introduction, Stability, Phase Space and Invariant Sets - 3
Link NOC:Introductory Non-Linear Dynamics Lecture 4 - Maps and Flows. Simple Examples of Dynamics Systems - 1
Link NOC:Introductory Non-Linear Dynamics Lecture 5 - Maps and Flows. Simple Examples of Dynamics Systems - 2
Link NOC:Introductory Non-Linear Dynamics Lecture 6 - Logistic map. Simple Examples of Bifurcations
Link NOC:Introductory Non-Linear Dynamics Lecture 7 - Bifurcation Diagrams. Period 3 Implies Chaos. Characterizing Chaos
Link NOC:Introductory Non-Linear Dynamics Lecture 8 - Characterizing The Period-Doubling Route to Chaos
Link NOC:Introductory Non-Linear Dynamics Lecture 9 - Lyapunov Exponents; Invariant measures
Link NOC:Introductory Non-Linear Dynamics Lecture 10 - Intermittency. Crises
Link NOC:Introductory Non-Linear Dynamics Lecture 11 - Fractals
Link NOC:Introductory Non-Linear Dynamics Lecture 12 - Chaos in Flows. The Lorenz and Rossler Systems
Link NOC:Introductory Non-Linear Dynamics Lecture 13 - The Baker and Horseshoe Maps
Link NOC:Introductory Non-Linear Dynamics Lecture 14 - Hamiltonian Chaos - 1
Link NOC:Introductory Non-Linear Dynamics Lecture 15 - Hamiltonian Chaos - 2
Link NOC:Principles of Organic Synthesis Lecture 1 - Aldol Reaction
Link NOC:Principles of Organic Synthesis Lecture 2 - Perkin, Claisen and Thorpe Reactions
Link NOC:Principles of Organic Synthesis Lecture 3 - Reaction of Enolates
Link NOC:Principles of Organic Synthesis Lecture 4 - Mannich Reaction
Link NOC:Principles of Organic Synthesis Lecture 5 - Reaction of Alkenes and Carbonyl Compounds
Link NOC:Principles of Organic Synthesis Lecture 6 - Friedel-Crafts and Prins Reactions
Link NOC:Principles of Organic Synthesis Lecture 7 - Grignard Reagents
Link NOC:Principles of Organic Synthesis Lecture 8 - Organolithium Reagents
Link NOC:Principles of Organic Synthesis Lecture 9 - Organocopper, Organozinc and Organomercury Reagents
Link NOC:Principles of Organic Synthesis Lecture 10 - Ritter Reaction and Gabriel Synthesis
Link NOC:Principles of Organic Synthesis Lecture 11 - Reactions of imines and enamines, synthesis of alkaloids and amino acids
Link NOC:Principles of Organic Synthesis Lecture 12 - Reactions of electrophilic and nucleophilic nitrogens, synthesis of amino acids and peptides
Link NOC:Principles of Organic Synthesis Lecture 13 - Principles, effect of substituents and carbon-carbon bond formation
Link NOC:Principles of Organic Synthesis Lecture 14 - Formylation/acylation and related reactions
Link NOC:Principles of Organic Synthesis Lecture 15 - Nitration, Sulfonation and other reactions
Link NOC:Principles of Organic Synthesis Lecture 16 - Principle, Substitution mechanism and reactions of Benzyne
Link NOC:Principles of Organic Synthesis Lecture 17 - Schiemann Reaction, Ullmann reaction and Stephens-Castro coupling
Link NOC:Principles of Organic Synthesis Lecture 18 - Ziegler Alkylation, Chichibabin Reaction, Von Richter Rearrangement, Smiles Rearrangement, Bamberger Rearrangement and Bucherer Reaction
Link NOC:Principles of Organic Synthesis Lecture 19 - Preparation, properties and reactions
Link NOC:Principles of Organic Synthesis Lecture 20 - Coupling reactions, Japp-Klingemann reaction and Tiffeneau-Demjanov rearrangement
Link NOC:Principles of Organic Synthesis Lecture 21 - Applications of diazonium salts
Link NOC:Principles of Organic Synthesis Lecture 22 - Wagner-Meerwein rearrangment, Pinacol rearrangment, Benzilic acid rearrangment and Arndt-Eistert synthesis
Link NOC:Principles of Organic Synthesis Lecture 23 - Rearrangement of halogen, oxygen, sulfur and nitrogen containing centre
Link NOC:Principles of Organic Synthesis Lecture 24 - Rearrangement to electron-Rich carbon
Link NOC:Principles of Organic Synthesis Lecture 25 - Reactivity and several reactions
Link NOC:Principles of Organic Synthesis Lecture 26 - Reactions of sulfur and silicon containing reagents
Link NOC:Principles of Organic Synthesis Lecture 27 - Preparation and reactions of organoborane and organotin reagents
Link NOC:Principles of Organic Synthesis Lecture 28 - Formation of carbon-carbon and carbon-halogen bonds
Link NOC:Principles of Organic Synthesis Lecture 29 - Cu, Mn, Sm, and Sn Based Reactions, Acyloin Condensation
Link NOC:Principles of Organic Synthesis Lecture 30 - C-N, C-O bond formation and decarboxylation
Link NOC:Reagents in Organic Synthesis Lecture 1 - Chromium Based Reagents for Oxidation
Link NOC:Reagents in Organic Synthesis Lecture 2 - Non-metal based Reagents for Oxidation
Link NOC:Reagents in Organic Synthesis Lecture 3 - Organic Peroxides
Link NOC:Reagents in Organic Synthesis Lecture 4 - Oxidation Mediated by DDQ, CAN and SeO2
Link NOC:Reagents in Organic Synthesis Lecture 5 - Oxidation Mediated by Mn and Ag
Link NOC:Reagents in Organic Synthesis Lecture 6 - Oxidation by Ru, Hypervalent Iodine, Al and Na based Reagents
Link NOC:Reagents in Organic Synthesis Lecture 7 - Na and Li Metal based Reduction
Link NOC:Reagents in Organic Synthesis Lecture 8 - Hydride based Reduction
Link NOC:Reagents in Organic Synthesis Lecture 9 - Hydrogenation
Link NOC:Reagents in Organic Synthesis Lecture 10 - Al, Zn and Li Based Reagents for Reduction
Link NOC:Reagents in Organic Synthesis Lecture 11 - Reduction With Boranes, Diimide and Trialkylsilanes
Link NOC:Reagents in Organic Synthesis Lecture 12 - Li Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 13 - Mg and Na Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 14 - B Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 15 - B and Al Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 16 - S Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 17 - P Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 18 - Si and Pb Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 19 - Sn and Bi Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 20 - Ti Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 21 - Ru Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 22 - Pd Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 23 - Cu Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 24 - Cr and Mn Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 25 - Zn and Hg Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 26 - Au Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 27 - Fe and Co Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 28 - Ag and Rh Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 29 - Ni, Pt and Ir Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 30 - Introduction to Lanthanides and Sm Based Reagents
Link NOC:Reagents in Organic Synthesis Lecture 31 - Samarium(Ii) Iodide Based Reagents in Organic Synthesis
Link NOC:Reagents in Organic Synthesis Lecture 32 - Sm and Yb Based Reagents in Organic Synthesis
Link NOC:Thermodynamics: Classical to Statistical Lecture 1 - Cocepts of heat and work; First Law of Thermodynamics
Link NOC:Thermodynamics: Classical to Statistical Lecture 2 - Concepts of enthalpy and heat capacity
Link NOC:Thermodynamics: Classical to Statistical Lecture 3 - Introduction to entropy
Link NOC:Thermodynamics: Classical to Statistical Lecture 4 - Calculation of entropy for various processes
Link NOC:Thermodynamics: Classical to Statistical Lecture 5 - Gibbs and Helmholtz free energy
Link NOC:Thermodynamics: Classical to Statistical Lecture 6 - Introduction to chemical potential
Link NOC:Thermodynamics: Classical to Statistical Lecture 7 - Clapeyron equation and phase transition; concept of fugacity
Link NOC:Thermodynamics: Classical to Statistical Lecture 8 - Calculation of fugacity; free energy of mixing
Link NOC:Thermodynamics: Classical to Statistical Lecture 9 - Partial molar quantities; excess thermodynamic quantities
Link NOC:Thermodynamics: Classical to Statistical Lecture 10 - Concept of activity and activity coefficients; Debye-Huckel limiting law
Link NOC:Thermodynamics: Classical to Statistical Lecture 11 - Phase Diagram of one component systems
Link NOC:Thermodynamics: Classical to Statistical Lecture 12 - Phase Diagram of two component systems
Link NOC:Thermodynamics: Classical to Statistical Lecture 13 - Phase Diagram of three component system; one dimensional random walk
Link NOC:Thermodynamics: Classical to Statistical Lecture 14 - Macroscopic and microscopic states; Boltzmann distribution; Canonical partition function
Link NOC:Thermodynamics: Classical to Statistical Lecture 15 - Calculation of different thermodynamical quantities using canonical partition function
Link NOC:Thermodynamics: Classical to Statistical Lecture 16 - Introduction to molecular partition function
Link NOC:Thermodynamics: Classical to Statistical Lecture 17 - Translational, electronic and nuclear partition function
Link NOC:Thermodynamics: Classical to Statistical Lecture 18 - Rotational partition function
Link NOC:Thermodynamics: Classical to Statistical Lecture 19 - Vibrational partitition function; Introduction to grand canonical ensemble
Link NOC:Thermodynamics: Classical to Statistical Lecture 20 - Grand canonical distribution; Introduction to microcanonical ensemble
Link NOC:Thermodynamics: Classical to Statistical Lecture 21 - Problems on classical thermodynamics - 1
Link NOC:Thermodynamics: Classical to Statistical Lecture 22 - Problems on classical thermodynamics - 2
Link NOC:Thermodynamics: Classical to Statistical Lecture 23 - Problems on statistical thermodynamics - 1
Link NOC:Thermodynamics: Classical to Statistical Lecture 24 - Problems on statistical thermodynamics - 2
Link NOC:Thermodynamics: Classical to Statistical Lecture 25 - Problems on statistical thermodynamics - 3
Link NOC:Thermodynamics: Classical to Statistical Lecture 26 - Fermi-Dirac and Bose-Einstein statistics
Link NOC:Thermodynamics: Classical to Statistical Lecture 27 - Ideal Fermi gas
Link NOC:Thermodynamics: Classical to Statistical Lecture 28 - Ideal Bose gas;Introduction to Bose-Einstein condensation
Link NOC:Thermodynamics: Classical to Statistical Lecture 29 - Bose-Einstein condensations
Link NOC:Thermodynamics: Classical to Statistical Lecture 30 - Nuclear spin statistics; Ortho- and para-hydrogens
Link NOC:Thermodynamics: Classical to Statistical Lecture 31 - Specific Heats of solids
Link NOC:Thermodynamics: Classical to Statistical Lecture 32 - Problems on statistical thermodynamics - 4
Link NOC:Thermodynamics: Classical to Statistical Lecture 33 - Advance problems - 1
Link NOC:Thermodynamics: Classical to Statistical Lecture 34 - Advance Problems - 2
Link NOC:Thermodynamics: Classical to Statistical Lecture 35 - Advance Problems - 3
Link NOC:Thermodynamics: Classical to Statistical Lecture 36 - Advance Problems - 4
Link NOC:Thermodynamics: Classical to Statistical Lecture 37 - Advance Problems - 5
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 1 - Importance of Biomolecules
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 2 - DNA double helix: Chemical parameters
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 3 - DNA and Proteins
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 4 - Amino acids and Proteins
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 5 - Protein 3D structures, folding and denaturation
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 6 - Chemical synthesis pyrimidine nucleobases
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 7 - Chemical synthesis purine nucleobases, Prebiotic chemistry
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 8 - Synthesis of nucleosides
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 9 - Solid phase DNA synthesis
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 10 - Chemistry and Biology of DNA Replication
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 11 - Chemistry of Polymerase Chain Reaction
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 12 - Major components and steps involved in Polymerase chain reaction
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 13 - DNA sequencing: Sanger's di-deoxy method
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 14 - DNA sequencing: Maxam- Gilbert method
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 15 - Numerical Problem-1
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 16 - Sugar Chemistry
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 17 - Chemistry behind DNA damage and mutation
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 18 - Chemistry behind DNA damage and mutation
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 19 - DNA repair
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 20 - Transcription - The transfer of genetic information from DNA to mRNA
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 21 - Translation - The transfer of genetic information from mRNA to protein I
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 22 - Translation - The transfer of genetic information from mRNA to protein II
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 23 - Role of Ribosome in protein synthesis and the concept of codon
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 24 - Protein sequencing using Sanger's and Edman's degradation methods
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 25 - Mass spectroscopy and other sequencing methods for large proteins
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 26 - Solution phase peptide synthesis: mechanism and end protection
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 27 - Peptide coupling agents, Solid phase synthesis, peptide based therapeutics
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 28 - Spectroscopic techniques
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 29 - Spectrospic techniques - II and Purification technique-I of biomolecules
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 30 - Purification techniques - II and Characteriation techniques of biomolecules
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 31 - Molecular probes: PNA and LNA-I
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 32 - Molecular Probes: PNA and LNA-II
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 33 - Carbohydrate chemistry - I: Introduction and Synthesis
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 34 - Carbohydrate chemistry - II: Polysaccharides and its nanoparticles
Link NOC:Essentials of Biomolecules: Nucleic Acids and Peptides Lecture 35 - Carbohydrate chemistry - III: Synthesis of nanoparticles; Recap of all modules
Link Chemistry of Materials Lecture 1 - Introduction to Materials Chemistry
Link Chemistry of Materials Lecture 2 - Preparative routes: Conventional - Precursor technique - I
Link Chemistry of Materials Lecture 3 - Preparative routes: Conventional - Precursor technique - II
Link Chemistry of Materials Lecture 4 - Preparative routes: Un Conventional - Soncochemistry technique - II
Link Chemistry of Materials Lecture 5 - Preparative routes: Un Conventional - Soncochemistry technique - II
Link Chemistry of Materials Lecture 6 - Preparative routes: Un Conventional - Combustion technique
Link Chemistry of Materials Lecture 7 - Preparative routes: Un Conventional - Microwave technique
Link Chemistry of Materials Lecture 8 - Preparative routes: High Pressure - Hydrothermal Technique
Link Chemistry of Materials Lecture 9 - Preparative routes: Coventional Solid State Technique
Link Chemistry of Materials Lecture 10 - Molecular Beam Epitaxy: Monolayers to Multilayers
Link Chemistry of Materials Lecture 11 - Pulsed Laser Deposition: Oxide thin films
Link Chemistry of Materials Lecture 12 - Pulsed Electron Deposition: From oxides to polymeric films and devices
Link Chemistry of Materials Lecture 13 - Sputtering deposited thin films and applications
Link Chemistry of Materials Lecture 14 - Crystal growth-Single crystals.
Link Chemistry of Materials Lecture 15 - Applications of X-ray diffraction
Link Chemistry of Materials Lecture 16 - Applications of X-ray Photoelectron spectroscopy
Link Chemistry of Materials Lecture 17 - Applications of X-ray Absorption spectroscopy
Link Chemistry of Materials Lecture 18 - Applications of Thermal analysis techniques
Link Chemistry of Materials Lecture 19 - Applications of Scanning Tunneling microscopy
Link Chemistry of Materials Lecture 20 - Applications of Electron Microscopy
Link Chemistry of Materials Lecture 21 - Case Study of ZnO
Link Chemistry of Materials Lecture 22 - Magnetic materials - I
Link Chemistry of Materials Lecture 23 - Magnetic Materials - II
Link Chemistry of Materials Lecture 24 - Magnetic Materials - III & Related Phenomena
Link Chemistry of Materials Lecture 25 - Shape Memory Materials
Link Chemistry of Materials Lecture 26 - Spintronic Materials - I Colossal Magentoresistive Oxides
Link Chemistry of Materials Lecture 27 - Spintronic Materials - II Giant Magnetoresistive Materials
Link Chemistry of Materials Lecture 28 - Spintronic Materials - III Tunelling Magnetoresistive Materials
Link Chemistry of Materials Lecture 29 - Spintronic Materials - IV Dilute Magnetic Semicondcutors
Link Chemistry of Materials Lecture 30 - High Tc Superconductors
Link Chemistry of Materials Lecture 31 - The New Carbon family - I - Fullerenes and Nanotubes
Link Chemistry of Materials Lecture 32 - The New Carbon family - II - Graphene
Link Chemistry of Materials Lecture 33 - Optoelectronic Materials - I - OLEDS
Link Chemistry of Materials Lecture 34 - Optoelectronic Materials - II - OLEDS
Link Chemistry of Materials Lecture 35 - Inorganic Phosphors - I
Link Chemistry of Materials Lecture 36 - Inorganic Phosphors - II
Link Chemistry of Materials Lecture 37 - Phosphor Materials
Link Chemistry of Materials Lecture 38 - Solar Cells
Link Chemistry of Materials Lecture 39 - Interview with C N R Rao and Interview with E C Subba Rao
Link Chemistry of Materials Lecture 40 - Perceptions & Projections
Link Mathematics for Chemistry Lecture 1 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 2 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 3 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 4 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 5 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 6 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 7 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 8 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 9 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 10 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 11 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 12 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 13 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 14 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 15 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 16 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 17 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 18 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 19 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 20 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 21 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 22 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 23 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 24 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 25 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 26 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 27 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 28 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 29 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 30 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 31 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 32 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 33 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 34 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 35 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 36 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 37 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 38 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 39 - Mathematics for Chemistry
Link Mathematics for Chemistry Lecture 40 - Mathematics for Chemistry
Link Advance Analytical Course Lecture 1 - Advance Analytical Course
Link Advance Analytical Course Lecture 2 - Advance Analytical Course
Link Advance Analytical Course Lecture 3 - Advance Analytical Course
Link Advance Analytical Course Lecture 4 - Advance Analytical Course
Link Advance Analytical Course Lecture 5 - Advance Analytical Course
Link Advance Analytical Course Lecture 6 - Advance Analytical Course
Link Advance Analytical Course Lecture 7 - Advance Analytical Course
Link Advance Analytical Course Lecture 8 - Advance Analytical Course
Link Advance Analytical Course Lecture 9 - Advance Analytical Course
Link Advance Analytical Course Lecture 10 - Advance Analytical Course
Link Advance Analytical Course Lecture 11 - Advance Analytical Course
Link Advance Analytical Course Lecture 12 - Advance Analytical Course
Link Advance Analytical Course Lecture 13 - Advance Analytical Course
Link Advance Analytical Course Lecture 14 - Advance Analytical Course
Link Advance Analytical Course Lecture 15 - Advance Analytical Course
Link Advance Analytical Course Lecture 16 - Advance Analytical Course
Link Advance Analytical Course Lecture 17 - Advance Analytical Course
Link Advance Analytical Course Lecture 18 - Advance Analytical Course
Link Advance Analytical Course Lecture 19 - Advance Analytical Course
Link Advance Analytical Course Lecture 20 - Advance Analytical Course
Link Advance Analytical Course Lecture 21 - Advance Analytical Course
Link Advance Analytical Course Lecture 22 - Advance Analytical Course
Link Advance Analytical Course Lecture 23 - Advance Analytical Course
Link Advance Analytical Course Lecture 24 - Advance Analytical Course
Link Advance Analytical Course Lecture 25 - Advance Analytical Course
Link Advance Analytical Course Lecture 26 - Advance Analytical Course
Link Advance Analytical Course Lecture 27 - Advance Analytical Course
Link Advance Analytical Course Lecture 28 - Advance Analytical Course
Link Advance Analytical Course Lecture 29 - Advance Analytical Course
Link Advance Analytical Course Lecture 30 - Advance Analytical Course
Link Advance Analytical Course Lecture 31 - Advance Analytical Course
Link Advance Analytical Course Lecture 32 - Advance Analytical Course
Link Advance Analytical Course Lecture 33 - Advance Analytical Course
Link Advance Analytical Course Lecture 34 - Advance Analytical Course
Link Advance Analytical Course Lecture 35 - Advance Analytical Course
Link Advance Analytical Course Lecture 36 - Advance Analytical Course
Link Advance Analytical Course Lecture 37 - Advance Analytical Course
Link Advance Analytical Course Lecture 38 - Advance Analytical Course
Link Advance Analytical Course Lecture 39 - Advance Analytical Course
Link Advance Analytical Course Lecture 40 - Advance Analytical Course
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 1
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 2
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 3
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 4
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 5
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 6
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 7
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 8
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 9
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 10
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 11
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 12
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 13
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 14
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 15
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 16
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 17
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 18
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 19
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 20
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 21
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 22
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 23
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 24
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 25
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 26
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 27
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 28
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 29
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 30
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 31
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 32
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 33
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 34
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 35
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 36
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 37
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 38
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 39
Link NOC:Chemical Applications of Symmetry and Group Theory Lecture 40
Link NOC:Mathematics for Chemistry Lecture 1 - Errors, precision and accuracy
Link NOC:Mathematics for Chemistry Lecture 2 - Probability and distributions
Link NOC:Mathematics for Chemistry Lecture 3 - Gaussian distribution and integrals
Link NOC:Mathematics for Chemistry Lecture 4 - Gaussian distribution, integrals, averages
Link NOC:Mathematics for Chemistry Lecture 5 - Practice problems 1
Link NOC:Mathematics for Chemistry Lecture 6 - Vectors and Vector Spaces
Link NOC:Mathematics for Chemistry Lecture 7 - Linear Independence
Link NOC:Mathematics for Chemistry Lecture 8 - Scalar and vector fields
Link NOC:Mathematics for Chemistry Lecture 9 - Gradient, divergence and curl
Link NOC:Mathematics for Chemistry Lecture 10 - Practice problems 2
Link NOC:Mathematics for Chemistry Lecture 11 - Line integrals, Potential Theory
Link NOC:Mathematics for Chemistry Lecture 12 - Surface and Volume Integrals
Link NOC:Mathematics for Chemistry Lecture 13 - Matrices
Link NOC:Mathematics for Chemistry Lecture 14 - Linear Systems, Cramer's Rule
Link NOC:Mathematics for Chemistry Lecture 15 - Practice Problems 3
Link NOC:Mathematics for Chemistry Lecture 16 - Rank and Inverse of a Matrix
Link NOC:Mathematics for Chemistry Lecture 17 - Eigenvalues and Eigenvectors
Link NOC:Mathematics for Chemistry Lecture 18 - Special matrices
Link NOC:Mathematics for Chemistry Lecture 19 - Spectral decomposition and Normal modes
Link NOC:Mathematics for Chemistry Lecture 20 - Practice Problems 4
Link NOC:Mathematics for Chemistry Lecture 21 - Differential equations, Order
Link NOC:Mathematics for Chemistry Lecture 22 - Exact and Inexact differentials
Link NOC:Mathematics for Chemistry Lecture 23 - Integrating Factors
Link NOC:Mathematics for Chemistry Lecture 24 - System of 1st order ODEs, matrix methods
Link NOC:Mathematics for Chemistry Lecture 25 - Practice Problems 5
Link NOC:Mathematics for Chemistry Lecture 26 - Types of 2nd order ODEs, nature of solutions
Link NOC:Mathematics for Chemistry Lecture 27 - Homogeneous 2nd order ODEs
Link NOC:Mathematics for Chemistry Lecture 28 - Homogeneous and nonhomogeneous equations
Link NOC:Mathematics for Chemistry Lecture 29 - Nonhomogeneous equations – Variation of parameters
Link NOC:Mathematics for Chemistry Lecture 30 - Practice Problems 6
Link NOC:Mathematics for Chemistry Lecture 31 - Power series method for solving Legendre DE
Link NOC:Mathematics for Chemistry Lecture 32 - Properties of Legendre Polynomials
Link NOC:Mathematics for Chemistry Lecture 33 - Associated Legendre Polynomials, Spherical Harmonics
Link NOC:Mathematics for Chemistry Lecture 34 - Hermite Polynomials, Solution of Quantum Harmonic Oscillator
Link NOC:Mathematics for Chemistry Lecture 35 - Practice Problems 7
Link NOC:Mathematics for Chemistry Lecture 36 - Conditions for power series solution
Link NOC:Mathematics for Chemistry Lecture 37 - Frobenius Method, Bessel Functions
Link NOC:Mathematics for Chemistry Lecture 38 - Properties of Bessel Functions, circular boundary problems
Link NOC:Mathematics for Chemistry Lecture 39 - Leguerre Polynomials, solution to radial part of H-atom
Link NOC:Mathematics for Chemistry Lecture 40 - Practice Problems 8
Link NOC:Quantum Computing Lecture 1 - Introduction - Motivation and Overview
Link NOC:Quantum Computing Lecture 2 - Introduction - Technical Details
Link NOC:Quantum Computing Lecture 3 - Introduction - Basic tools
Link NOC:Quantum Computing Lecture 4 - Computational Tools
Link NOC:Quantum Computing Lecture 5 - Quantum Measurement and Teleportation
Link NOC:Quantum Computing Lecture 6 - Quantum Teleportation and Cryptography
Link NOC:Quantum Computing Lecture 7 - DJ Algorithm and Implementation Aspects
Link NOC:Quantum Computing Lecture 8 - Grover's Algorithm
Link NOC:Quantum Computing Lecture 9 - Basics of Shor's Algorithm
Link NOC:Quantum Computing Lecture 10 - Shor's Algorithm and Quantum Fourier Transform (QFT)
Link NOC:Quantum Computing Lecture 11 - Basics of Quantum Mechanics
Link NOC:Quantum Computing Lecture 12 - Modern look at Quantum Mechanics
Link NOC:Quantum Computing Lecture 13 - Basics of NMR
Link NOC:Quantum Computing Lecture 14 - Concepts in NMR Quantum Computing
Link NOC:Quantum Computing Lecture 15 - Laser Basics
Link NOC:Quantum Computing Lecture 16 - Continuous Wave Lasers
Link NOC:Quantum Computing Lecture 17 - Pulsed Lasers
Link NOC:Quantum Computing Lecture 18 : Optical Implementation 'Linear Approach
Link NOC:Quantum Computing Lecture 19 : Various Aspects of Linear Optical Quantum Computing
Link NOC:Quantum Computing Lecture 20 : Laser Experimental Implementation for Grover's Algorithm
Link NOC:Quantum Computing Lecture 21 - Optical Implementation
Link NOC:Quantum Computing Lecture 22 - Solutions to problem set - 1
Link NOC:Quantum Computing Lecture 23 - Basics of Ion Traps
Link NOC:Quantum Computing Lecture 24 - Applications of Ion Traps in QIQC
Link NOC:Quantum Computing Lecture 25 - Reviewing Concepts and clarifying problems - 1
Link NOC:Quantum Computing Lecture 26 - Reviewing Concepts and clarifying problems - 2
Link NOC:Quantum Computing Lecture 27 - Qubits used in Commercial Quantum Computing
Link NOC:Quantum Computing Lecture 28 - Spintronics Quantum Computing
Link NOC:Quantum Computing Lecture 29 - Back to Basics - I
Link NOC:Quantum Computing Lecture 30 - Back to Basics - II
Link NOC:Quantum Computing Lecture 31 - Understanding Implementation Issues from the Basics - I
Link NOC:Quantum Computing Lecture 32 - Understanding Implementation Issues from the Basics - II
Link NOC:Quantum Computing Lecture 33 - Implementation with Solid-State Super conducting Qubits
Link NOC:Quantum Computing Lecture 34 - Concept of Density Matrix for Quantum Computing
Link NOC:Quantum Computing Lecture 35 - Understanding the ensemble of Qubits from Density Matrix
Link NOC:Quantum Computing Lecture 36 - Understanding Quantum Measurement, Entanglement etc. in Quantum Computing using Density Matrix
Link NOC:Quantum Computing Lecture 37 - Principles: Quantum Mechanics and Computers
Link NOC:Quantum Computing Lecture 38 - Measurements: Single vs Ensemble Averaged
Link NOC:Quantum Computing Lecture 39 - Working of Quantum Computers: NMR QC
Link NOC:Quantum Computing Lecture 40 - Academic Development in Quantum Computing - I
Link NOC:Quantum Computing Lecture 41 - Academic Development in Quantum Computing - II
Link NOC:Quantum Computing Lecture 42 - Commercial Development in Quantum Computing Implementation
Link NOC:Quantum Computing Lecture 43 - Use of Atomic Quibts in Quantum Computing
Link NOC:Quantum Computing Lecture 44 - Futuristic Aspects in Implementing Quantum Computing - I
Link NOC:Quantum Computing Lecture 45 - Futuristic Aspects in Implementing Quantum Computing - II
Link NOC:Basics of Fluroscence Spectroscopy Lecture 1
Link NOC:Basics of Fluroscence Spectroscopy Lecture 2
Link NOC:Basics of Fluroscence Spectroscopy Lecture 3
Link NOC:Basics of Fluroscence Spectroscopy Lecture 4
Link NOC:Basics of Fluroscence Spectroscopy Lecture 5
Link NOC:Basics of Fluroscence Spectroscopy Lecture 6
Link NOC:Basics of Fluroscence Spectroscopy Lecture 7
Link NOC:Basics of Fluroscence Spectroscopy Lecture 8
Link NOC:Basics of Fluroscence Spectroscopy Lecture 9
Link NOC:Basics of Fluroscence Spectroscopy Lecture 10
Link NOC:Basics of Fluroscence Spectroscopy Lecture 11
Link NOC:Basics of Fluroscence Spectroscopy Lecture 12
Link NOC:Basics of Fluroscence Spectroscopy Lecture 13
Link NOC:Basics of Fluroscence Spectroscopy Lecture 14
Link NOC:Basics of Fluroscence Spectroscopy Lecture 15
Link NOC:Basics of Fluroscence Spectroscopy Lecture 16
Link NOC:Basics of Fluroscence Spectroscopy Lecture 17
Link NOC:Basics of Fluroscence Spectroscopy Lecture 18
Link NOC:Basics of Fluroscence Spectroscopy Lecture 19
Link NOC:Basics of Fluroscence Spectroscopy Lecture 20
Link NOC:Basics of Fluroscence Spectroscopy Lecture 21
Link NOC:Basics of Fluroscence Spectroscopy Lecture 22
Link NOC:Basics of Fluroscence Spectroscopy Lecture 23
Link NOC:Basics of Fluroscence Spectroscopy Lecture 24
Link NOC:Basics of Fluroscence Spectroscopy Lecture 25
Link NOC:Basics of Fluroscence Spectroscopy Lecture 26
Link NOC:Basics of Fluroscence Spectroscopy Lecture 27
Link NOC:Basics of Fluroscence Spectroscopy Lecture 28
Link NOC:Basics of Fluroscence Spectroscopy Lecture 29
Link NOC:Basics of Fluroscence Spectroscopy Lecture 30
Link NOC:Basics of Fluroscence Spectroscopy Lecture 31
Link NOC:Basics of Fluroscence Spectroscopy Lecture 32
Link NOC:Basics of Fluroscence Spectroscopy Lecture 33
Link NOC:Basics of Fluroscence Spectroscopy Lecture 34
Link NOC:Basics of Fluroscence Spectroscopy Lecture 35
Link NOC:Basics of Fluroscence Spectroscopy Lecture 36
Link NOC:Basics of Fluroscence Spectroscopy Lecture 37
Link NOC:Basics of Fluroscence Spectroscopy Lecture 38
Link NOC:Basics of Fluroscence Spectroscopy Lecture 39
Link NOC:Basics of Fluroscence Spectroscopy Lecture 40
Link NOC:Laser - Fundamentals and Applications Lecture 1 - Unique properties of LASERs and their applications
Link NOC:Laser - Fundamentals and Applications Lecture 2 - LASER and its history
Link NOC:Laser - Fundamentals and Applications Lecture 3 - Interaction of Light with matter
Link NOC:Laser - Fundamentals and Applications Lecture 4 - Einsteins Concept of stimulated emission
Link NOC:Laser - Fundamentals and Applications Lecture 5 - Calculation of Einsteins coefficient
Link NOC:Laser - Fundamentals and Applications Lecture 6 - Population inversion, 2-level system and 3-level system
Link NOC:Laser - Fundamentals and Applications Lecture 7 - 3-level System and 4-level system
Link NOC:Laser - Fundamentals and Applications Lecture 8 - Components of LASERs
Link NOC:Laser - Fundamentals and Applications Lecture 9 - Modes of LASER cavity and standing waves
Link NOC:Laser - Fundamentals and Applications Lecture 10 - Transverse Modes of LASER cavity
Link NOC:Laser - Fundamentals and Applications Lecture 11 - Threshold Condition
Link NOC:Laser - Fundamentals and Applications Lecture 12 - Properties of Laser: Directionality and Intensity
Link NOC:Laser - Fundamentals and Applications Lecture 13 - Properties of Laser: Coherence and Monochromaticity
Link NOC:Laser - Fundamentals and Applications Lecture 14 - Continuous and Pulsed Lasers
Link NOC:Laser - Fundamentals and Applications Lecture 15 - Some Numerical problem
Link NOC:Laser - Fundamentals and Applications Lecture 16 - Cavity Dumping
Link NOC:Laser - Fundamentals and Applications Lecture 17 - Q-switching
Link NOC:Laser - Fundamentals and Applications Lecture 18 - Q-switching and Pockels effect
Link NOC:Laser - Fundamentals and Applications Lecture 19 - Passive Q-switching, Mode-Locking
Link NOC:Laser - Fundamentals and Applications Lecture 20 - Mode Locking
Link NOC:Laser - Fundamentals and Applications Lecture 21 - Mode - locking
Link NOC:Laser - Fundamentals and Applications Lecture 22 - Mode - locking (Continued...)
Link NOC:Laser - Fundamentals and Applications Lecture 23 - Passive Mode - locking and Types of LASERs
Link NOC:Laser - Fundamentals and Applications Lecture 24 - Solid state LASERs
Link NOC:Laser - Fundamentals and Applications Lecture 25 - Semiconductor LASERs and Gas LASERs
Link NOC:Laser - Fundamentals and Applications Lecture 26 - Gas LASERs
Link NOC:Laser - Fundamentals and Applications Lecture 27 - Chemical and Dye LASERs
Link NOC:Laser - Fundamentals and Applications Lecture 28 - Introduction to Non Linear Optics
Link NOC:Laser - Fundamentals and Applications Lecture 29 - Non Linear Optics
Link NOC:Laser - Fundamentals and Applications Lecture 30 - 2nd order Nonlinear optics
Link NOC:Laser - Fundamentals and Applications Lecture 31 - Non-linear optical processes
Link NOC:Laser - Fundamentals and Applications Lecture 32 - Aspects of SHG and Application of non-linear optics
Link NOC:Laser - Fundamentals and Applications Lecture 33 - Application of LASER: LIDAR
Link NOC:Laser - Fundamentals and Applications Lecture 34 - Application of Laser: Laser Spectroscopy
Link NOC:Laser - Fundamentals and Applications Lecture 35 - Application of Laser: Enrichment of Isotope
Link NOC:Laser - Fundamentals and Applications Lecture 36 - Laser Induced Chemistry
Link NOC:Laser - Fundamentals and Applications Lecture 37 - Laser Induced Chemistry and Ultrafast chemical Dynamics
Link NOC:Laser - Fundamentals and Applications Lecture 38 - Lasers in Medical Sciences
Link NOC:Laser - Fundamentals and Applications Lecture 39 - Lasers in Material sciences and engineering and Optical Communications
Link NOC:Laser - Fundamentals and Applications Lecture 40 - Laser safety and summary
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 1 - Vectors, Vector Operations and Linear Independence
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 2 - Vector Operations, Generalization of Vectors
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 3 - Vector Differentiation, Vector Transformations
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 4 - Vector Integration, Line, Surface and Volume Integrals
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 5 - Practice Problems
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 6 - Matrix as a vector transformation, linear system
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 7 - Special Matrices: Symmetric, Orthogonal, Complex
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 8 - Rotational Matrices, Eigenvalues and Eigenvectors
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 9 - Determinants, Matrix Inverse
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 10 - Practice Problems
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 11 - Step Function, Delta Function
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 12 - Gamma Function, Error Function
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 13 - Spherical Polar Coordinates
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 14 - Cylindrical Polar Coordinates, Integrals
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 15 - Recap of Module 3, Practice Problems
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 16 - ODEs and PDEs, First order ODEs, system of 1st order ODEs
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 17 - First order ODEs, exact integrals, integrating factors
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 18 - System of first order ODEs, Linear first order ODEs
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 19 - General solution of a system of linear first order ODEs with constant coefficients
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 20 - Recap of Module 4, Practice problems
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 21 - Homogeneous 2nd Order ODE, Basis Functions
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 22 - Nonhomogeneous 2nd Order ODE
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 23 - Power Series Method of Solving ODEs
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 24 - Frobenius Method / Power Series Method
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 25 - Time-independent Schrodinger Equation for H-atom
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 26 - Maxima and Minima, Taylor Series
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 27 - Taylor Series for functions of several variables
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 28 - Critical Points of Functions
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 29 - Lagranges Method of Undetermined Multipliers
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 30 - Recap of Module 6, Practice Problems
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 31 - Nonlinear Differential Equations
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 32 - Phase Plane of A Pendulum
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 33 - Stability of Critical Points
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 34 - Population Dynamics Models
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 35 - Recap of Module 7, Practice Problems
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 36 - Fourier Series, Fourier Expansion of Periodic Functions
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 37 - (Part A): Fourier Expansions and Differential Equations
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 38 - (Part B): Fourier Expansions and Differential Equations
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 39 - Orthogonal Eigenfunctions, Sturm-Liouville Theory
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 40 - Recap of Module 8, Practice Problems
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 41 - Fourier Transforms
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 42 - Properties of Fourier Transforms
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 43 - Fourier Transforms and Partial Differential Equations
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 44 - Laplace Transforms
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 45 - Recap of Module 9, Practice Problems
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 46 - Partial Differential Equations, Boundary Conditions
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 47 - Separation of Variables
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 48 - (Part A): Two-dimensional Wave Equation, Bessel Functions
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 49 - (Part B): Two-dimensional Wave Equation, Bessel Functions
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 50 - Recap of Module 10, Practice Problems
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 51 - Discrete and Continuous Random Variables
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 52 - Probability Distribution Functions
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 53 - Poisson Distribution, Gaussain Distribution
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 54 - Error Estimates, Least Square Fit, Correlation Functions
Link NOC:Advanced Mathematical Methods for Chemistry Lecture 55 - Recap of Module 11, Practice Problems
Link NOC:Solid State Chemistry Lecture 1 - Nature of solid state and the solid state materials
Link NOC:Solid State Chemistry Lecture 2 - Thermodynamics of solids
Link NOC:Solid State Chemistry Lecture 3 - Crystallisation Kinetics
Link NOC:Solid State Chemistry Lecture 4 - Synthetic Strategy
Link NOC:Solid State Chemistry Lecture 5 - Review of week 1 and Practice problems
Link NOC:Solid State Chemistry Lecture 6 - Unit Cells
Link NOC:Solid State Chemistry Lecture 7 - Conventional Unit Cell and Primitive Unit Cell
Link NOC:Solid State Chemistry Lecture 8 - Bravais Lattices
Link NOC:Solid State Chemistry Lecture 9 - Bravais Lattices, Basis and crystal
Link NOC:Solid State Chemistry Lecture 10 - Summery of week 2 and Practices Problems
Link NOC:Solid State Chemistry Lecture 11 - Symmetry In Crystals, Point Symmetries
Link NOC:Solid State Chemistry Lecture 12 - Reflections, Inversions and Rotoinversions
Link NOC:Solid State Chemistry Lecture 13 - Schonflies and Hermann-Mauguin Conventions
Link NOC:Solid State Chemistry Lecture 14 - Fractional Coordinates, Planer Visualization
Link NOC:Solid State Chemistry Lecture 15 - Review of week 3 And Practice Problems
Link NOC:Solid State Chemistry Lecture 16 - Combining symmetry operations, translational symmetries
Link NOC:Solid State Chemistry Lecture 17 - Screw Axis
Link NOC:Solid State Chemistry Lecture 18 - Glide Planes
Link NOC:Solid State Chemistry Lecture 19 - Symmetry and Symmetry Notations
Link NOC:Solid State Chemistry Lecture 20 - Summary of week 4 and Practice Problems
Link NOC:Solid State Chemistry Lecture 21 - Crystal Systems
Link NOC:Solid State Chemistry Lecture 22 - Crystal Systems and Unit Cells
Link NOC:Solid State Chemistry Lecture 23 - Point Groups
Link NOC:Solid State Chemistry Lecture 24 - Space Groups
Link NOC:Solid State Chemistry Lecture 25 - Week 5 Summary and Practice Problems
Link NOC:Solid State Chemistry Lecture 26 - 32 Crystal Classes Based on Symmetry
Link NOC:Solid State Chemistry Lecture 27 - Notation for 32 Crystal Classes
Link NOC:Solid State Chemistry Lecture 28 - Short Form of Hermann-Mauguin Notations
Link NOC:Solid State Chemistry Lecture 29 - Hermann - Mauguin notation for Space Groups
Link NOC:Solid State Chemistry Lecture 30 - Summary and Practice Problems
Link NOC:Solid State Chemistry Lecture 31 - Coordination number, Voids
Link NOC:Solid State Chemistry Lecture 32 - Lattice Imperfections and Crystals
Link NOC:Solid State Chemistry Lecture 33 - Line Planner and Bulk defects and crystals
Link NOC:Solid State Chemistry Lecture 34 - Thermodynamics of defects in crystals
Link NOC:Solid State Chemistry Lecture 35 - Review of Week 7,Practice Problems
Link NOC:Solid State Chemistry Lecture 36 - Miller Planes, Miller Indices
Link NOC:Solid State Chemistry Lecture 37 - Miller Indices for Hexagonal Systems, Distance between Planes
Link NOC:Solid State Chemistry Lecture 38 - X-ray diffraction, Bragg's Law, Reciprocal Lattice
Link NOC:Solid State Chemistry Lecture 39 - Reciprocal Lattice, XRD instrumentation
Link NOC:Solid State Chemistry Lecture 40 - Review of week 8, Practice Problems
Link NOC:Solid State Chemistry Lecture 41 - XRD - Analysis of Pattern
Link NOC:Solid State Chemistry Lecture 42 - Geometric Structure Factor - Missing Peaks
Link NOC:Solid State Chemistry Lecture 43 - X-Ray Crystallography
Link NOC:Solid State Chemistry Lecture 44 - Electron Microscopy
Link NOC:Solid State Chemistry Lecture 45 - Review of Week 9. Practice Problems
Link NOC:Solid State Chemistry Lecture 46 - Closed - Packed Structures and Voids
Link NOC:Solid State Chemistry Lecture 47 - Crystal Structures of Binary Compounds
Link NOC:Solid State Chemistry Lecture 48 - Perovskites and Spinals
Link NOC:Solid State Chemistry Lecture 49 - Space filling Polyhedra, Alloys
Link NOC:Solid State Chemistry Lecture 50 - Summary of Week 10 and Practice Problems
Link NOC:Solid State Chemistry Lecture 51 - Free electron Models
Link NOC:Solid State Chemistry Lecture 52 - Bloch Theorem
Link NOC:Solid State Chemistry Lecture 53 - Band Theory of Solids
Link NOC:Solid State Chemistry Lecture 54 - Bands in Higher Dimensions
Link NOC:Solid State Chemistry Lecture 55 - Summary of Week 11 and Practice Problems
Link NOC:Solid State Chemistry Lecture 56 - More about Band Theory, Crystal Momentum
Link NOC:Solid State Chemistry Lecture 57 - Density of States
Link NOC:Solid State Chemistry Lecture 58 - Metals, Insulators and Semiconductors
Link NOC:Solid State Chemistry Lecture 59 - Band Gap and Optical Properties
Link NOC:Solid State Chemistry Lecture 60 - Summary of Week 12 and Practice Problems
Link NOC:Bioinorganic Chemistry Lecture 1 - General Introduction and Prospects
Link NOC:Bioinorganic Chemistry Lecture 2 - Metals in Biology: Nature's Selection of Elements in Life
Link NOC:Bioinorganic Chemistry Lecture 3 - Metals in Biology: Control, Use and Enzymatic Action
Link NOC:Bioinorganic Chemistry Lecture 4 - Metals in Biology: Choice of Redox Active Metal Ions
Link NOC:Bioinorganic Chemistry Lecture 5 - Metals in Biology: Importance of Cobalt in Coenzyme-B12
Link NOC:Bioinorganic Chemistry Lecture 6 - Design Principles Used in Chemical Biology: Some Noteworthy Examples!
Link NOC:Bioinorganic Chemistry Lecture 7 - Design Principles Used in Chemical Biology: Role of Proteins in Controlling Reactivity!
Link NOC:Bioinorganic Chemistry Lecture 8 - Design Principles Used in Chemical Biology: Blue-Copper Proteins
Link NOC:Bioinorganic Chemistry Lecture 9 - Design Principles Used in Chemical Biology: Fixation of Nitrogen from Air
Link NOC:Bioinorganic Chemistry Lecture 10 - Life with Oxygen: Molecular and Chemical Properties of O2
Link NOC:Bioinorganic Chemistry Lecture 11 - Life with Oxygen: Cytochrome c oxidase
Link NOC:Bioinorganic Chemistry Lecture 12 - Life with Oxygen: Superoxide Dismutase Activity
Link NOC:Bioinorganic Chemistry Lecture 13 - Life with Oxygen: Catalase and Peroxidase Activities
Link NOC:Bioinorganic Chemistry Lecture 14 - Life with Oxygen: Oxygenase Activity
Link NOC:Bioinorganic Chemistry Lecture 15 - Life with Oxygen: O2-Carrying Proteins Hemocyanin and Hemerythrin
Link NOC:Bioinorganic Chemistry Lecture 16 - Life with Oxygen: O2-Carrying Proteins Hemoglobin and Myoglobin
Link NOC:Bioinorganic Chemistry Lecture 17 - Life with Oxygen: Reversible O2-binding and Transport
Link NOC:Bioinorganic Chemistry Lecture 18 - Life with Oxygen: Heme Oxygenase Activity
Link NOC:Bioinorganic Chemistry Lecture 19 - Metals in Medicine: Introduction to Medicinal Inorganic Chemistry
Link NOC:Bioinorganic Chemistry Lecture 20 - Metals in Medicine: Platinum-based Anti-Cancer Drugs
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 1 - Intro-Chemistry and Physics of Surfaces and Interfaces
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 2 - Historic perspective to surface science
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 3 - Creating surfaces from bulk lattices
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 4 - Reconstruction of surfaces
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 5 - Hexagonal lattice and miller bravais indices
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 6 - Introduction to ultra-high Vaccum and Preparation of Clean Surfaces
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 7 - Adsorption and the Energetic of Adsorption
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 8 - Nomenclature and types of Adlayers
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 9 - Thermal Desorption Spectroscopy
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 10 - Different types of Preparation methods for Thin Films
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 11 - Examples of PVD and CVD
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 12 - Moire Pattern at Solid-Solid Interface
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 13 - Growth Modes of Adlayers
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 14 - Energies that Control the Growth of Adlayers
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 15 - Kinetic and Thermodynamic Control in Adlayer Growth
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 16 - Molecular Adsorbates: Preparation
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 17 - Molecular Adsorbates: Factors Controlling Molecular Adlayer Formation - I
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 18 - Molecular Adsorbates: Factors Controlling Molecular Adlayer Formation - II
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 19 - Molecular Adsorbates: Factors Controlling Molecular Adlayer Formation - III
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 20 - Scanning Tunneling Microscopy
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 21 - Tip-vaccum Tunneling Junction
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 22 - Scanning Tunneling Spectroscopy - I
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 23 - Scanning Tunneling Spectroscopy - II
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 24 - Scanning Tunneling Spectroscopy: Applications - I
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 25 - Scanning Tunneling Spectroscopy: Applications - II
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 26 - Imaging Molecules and Atom Manipulation on Surfaces
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 27 - Single Molecule Manipulation on Surfaces
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 28 - Inelastic Tunneling Spectroscopy
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 29 - Ultra-violet Photo-electron Spectroscopy (UPS)
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 30 - Ultra-violet Photo-electron Spectroscopy (UPS): Applications
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 31 - X-ray Photo-electron Spectroscopy (XPS)
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 32 - X-Ray Photo-electron Spectroscopy (XPS): Applications - 1
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 33 - X-Ray Photo-electron Spectroscopy (XPS): Applications - 2
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 34 - 2D Molecular Materials on Surface - 1
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 35 - 2D Molecular Materials on Surface - 2
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 36 - Atomic Force Microscopy (AFM) - I
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 37 - Atomic Force Microscopy (AFM) - II
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 38 - Atomic Force Microscopy (AFM) - III
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 39 - Dynamics of Atoms on Surfaces
Link NOC:Chemistry and Physics of Surfaces and Interfaces Lecture 40 - Summary
Link NOC:Supramolecular Chemistry-I Lecture 1
Link NOC:Supramolecular Chemistry-I Lecture 2
Link NOC:Supramolecular Chemistry-I Lecture 3
Link NOC:Supramolecular Chemistry-I Lecture 4
Link NOC:Supramolecular Chemistry-I Lecture 5
Link NOC:Supramolecular Chemistry-I Lecture 6
Link NOC:Supramolecular Chemistry-I Lecture 7
Link NOC:Supramolecular Chemistry-I Lecture 8
Link NOC:Supramolecular Chemistry-I Lecture 9
Link NOC:Supramolecular Chemistry-I Lecture 10
Link NOC:Supramolecular Chemistry-I Lecture 11
Link NOC:Supramolecular Chemistry-I Lecture 12
Link NOC:Supramolecular Chemistry-I Lecture 13
Link NOC:Supramolecular Chemistry-I Lecture 14
Link NOC:Supramolecular Chemistry-I Lecture 15
Link NOC:Supramolecular Chemistry-I Lecture 16
Link NOC:Supramolecular Chemistry-I Lecture 17
Link NOC:Supramolecular Chemistry-I Lecture 18
Link NOC:Supramolecular Chemistry-I Lecture 19
Link NOC:Supramolecular Chemistry-I Lecture 20
Link NOC:Supramolecular Chemistry-I Lecture 21
Link NOC:Supramolecular Chemistry-I Lecture 22
Link NOC:Supramolecular Chemistry-I Lecture 23
Link NOC:Supramolecular Chemistry-I Lecture 24
Link NOC:Supramolecular Chemistry-I Lecture 25
Link NOC:Supramolecular Chemistry-I Lecture 26
Link NOC:Supramolecular Chemistry-I Lecture 27
Link NOC:Supramolecular Chemistry-I Lecture 28
Link NOC:Supramolecular Chemistry-I Lecture 29
Link NOC:Supramolecular Chemistry-I Lecture 30
Link NOC:Supramolecular Chemistry-I Lecture 31
Link NOC:Supramolecular Chemistry-I Lecture 32
Link NOC:Supramolecular Chemistry-I Lecture 33
Link NOC:Supramolecular Chemistry-I Lecture 34
Link NOC:Supramolecular Chemistry-I Lecture 35
Link NOC:Supramolecular Chemistry-I Lecture 36
Link NOC:Supramolecular Chemistry-I Lecture 37
Link NOC:Supramolecular Chemistry-I Lecture 38
Link NOC:Supramolecular Chemistry-I Lecture 39
Link NOC:Supramolecular Chemistry-I Lecture 40
Link Bio-inorganic chemistry Lecture 1 - Introduction
Link Bio-inorganic chemistry Lecture 2 - Iron Storage and Transport - I
Link Bio-inorganic chemistry Lecture 3 - Iron Storage and Transport - II
Link Bio-inorganic chemistry Lecture 4 - Iron Storage and Transport - III
Link Bio-inorganic chemistry Lecture 5 - Electron Transport Proteins - I
Link Bio-inorganic chemistry Lecture 6 - Electron transport Proteins - II
Link Bio-inorganic chemistry Lecture 7 - Electron Transport Proteins - III
Link Bio-inorganic chemistry Lecture 8 - Electron Transport Proteins - IV
Link Bio-inorganic chemistry Lecture 9 - Electron Transport Proteins - V
Link Bio-inorganic chemistry Lecture 10 - Electron Transport Proteins - VI
Link Bio-inorganic chemistry Lecture 11 - Electron Transport Proteins - VII
Link Bio-inorganic chemistry Lecture 12 - Electron Transport Proteins - VIII
Link Bio-inorganic chemistry Lecture 13 - Electron Transport Proteins - IX
Link Bio-inorganic chemistry Lecture 14 - Electron Transfer in Photosynthesis - I
Link Bio-inorganic chemistry Lecture 15 - Electron Transfer in Photosynthesis - II
Link Bio-inorganic chemistry Lecture 16 - Manganese Enzymes
Link Bio-inorganic chemistry Lecture 17 - Nickel Enzymes - I
Link Bio-inorganic chemistry Lecture 18 - Nickel Enzymes - II
Link Bio-inorganic chemistry Lecture 19 - Nickel Enzymes - III
Link Bio-inorganic chemistry Lecture 20 - Nickel Enzymes - IV
Link Bio-inorganic chemistry Lecture 21 - Nickel Enzymes - V
Link Bio-inorganic chemistry Lecture 22 - Molybdenum Enzymes - I
Link Bio-inorganic chemistry Lecture 23 - Molybdenum Enzymes - II
Link Bio-inorganic chemistry Lecture 24 - Molybdenum Enzymes - III
Link Bio-inorganic chemistry Lecture 25 - Molybdenum Enzymes - IV
Link Bio-inorganic chemistry Lecture 26 - Molybdenum Enzymes - V
Link Bio-inorganic chemistry Lecture 27 - Molybdenum Enzymes - VI
Link Bio-inorganic chemistry Lecture 28 - Molybdenum and Tungsten in Biology
Link Bio-inorganic chemistry Lecture 29 - Tungsten Enzymes - I
Link Bio-inorganic chemistry Lecture 30 - Tungsten Enzymes - II
Link Bio-inorganic chemistry Lecture 31 - Tungsten Enzymes - III
Link Bio-inorganic chemistry Lecture 32 - Tungsten Enzymes - IV
Link Bio-inorganic chemistry Lecture 33 - Vanadium Enzymes - I
Link Bio-inorganic chemistry Lecture 34 - Vanadium Enzymes - II
Link Bio-inorganic chemistry Lecture 35 - Vanadium Enzymes - III
Link Bio-inorganic chemistry Lecture 36 - Vanadium Enzymes - IV
Link Bio-inorganic chemistry Lecture 37 - Non-metals in Biology - I
Link Bio-inorganic chemistry Lecture 38 - Non-metals in Biology - II
Link Bio-inorganic chemistry Lecture 39 - Non-metals in Biology - III
Link Bio-inorganic chemistry Lecture 40 - Non-metals in Biology - IV
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 1 - Introduction
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 2 - Definition
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 3 - Classification of Ligands - I
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 4 - Classification of Ligands - II
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 5 - Ligands - III and Nomenclature - I
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 6 - Nomenclature - II
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 7 - Coordination Number - I
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 8 - Coordination Number - II
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 9 - Coordination Number - III
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 10 - Coordination Number - IV
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 11 - Isomerism - I
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 12 - Isomerism - II
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 13 - Coordination Equilibria - I
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 14 - Coordination Equilibria - II
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 15 - Bonding in Complexes - I
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 16 - Bonding in Complexes - II
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 17 - Bonding in Complexes - III
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 18 - Bonding in Complexes - IV
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 19 - Jahn-Teller Effect
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 20 - Spin Crossover and Colour
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 21 - Optical Spectra
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 22 - d-d Transitions
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 23 - Charge Transfer
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 24 - Orgel Diagram
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 25 - Tanabe Sugano Diagram
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 26 - MLCT Transitions
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 27 - Application of CFT
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 28 - Spinels
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 29 - Magnetochemistry
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 30 - Magnetic Properties
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 31 - Magnetic Measurements
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 32 - Ligand Field Theory
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 33 - Sigma Orbitals
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 34 - Pi Orbitals
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 35 - Reaction Mechanism - I
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 36 - Reaction Mechanism - II
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 37 - Reaction Mechanism - III
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 38 - Reaction Mechanism - IV
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 39 - Reaction Mechanism - V
Link Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 40 - Biological Inorganic Chemistry
Link Heterocyclic Chemistry Lecture 1 - Definition and Scope
Link Heterocyclic Chemistry Lecture 2 - Single - Step Methods for IVPs
Link Heterocyclic Chemistry Lecture 3 - Systematic Nomenclature
Link Heterocyclic Chemistry Lecture 4 - Nomenclature (Continued...) and Important Names
Link Heterocyclic Chemistry Lecture 5 - Overview of Structure Determination in Heterocyclic Chemistry
Link Heterocyclic Chemistry Lecture 6 - 15N NMR in Heterocyclic Chemistry
Link Heterocyclic Chemistry Lecture 7 - Effects of Ring Nitrogen - A
Link Heterocyclic Chemistry Lecture 8 - Effects of Ring Nitrogen - B
Link Heterocyclic Chemistry Lecture 9 - Effects of Ring Nitrogen - C
Link Heterocyclic Chemistry Lecture 10 - Oxidation in Heterocyclic Chemistry
Link Heterocyclic Chemistry Lecture 11 - Oxidation in Heterocyclic Chemistry (Continued...)
Link Heterocyclic Chemistry Lecture 12 - Reduction in Heterocyclic Chemistry
Link Heterocyclic Chemistry Lecture 13 - Radicals in Heterocylic Chemistry - I
Link Heterocyclic Chemistry Lecture 14 - Radicals in Heterocylic Chemistry - II
Link Heterocyclic Chemistry Lecture 15 - Lithiation for 5-membered heterocycles
Link Heterocyclic Chemistry Lecture 16 - Lithiation for 5-membered heterocycles (Continued...)
Link Heterocyclic Chemistry Lecture 17 - Lithiation of 6-membered heterocycle and non-aromatic heterocycles
Link Heterocyclic Chemistry Lecture 18 - Magnetiation and Zincation in Heterocyclic Chemistry
Link Heterocyclic Chemistry Lecture 19 - Transition metal catalyzed cross coupling
Link Heterocyclic Chemistry Lecture 20 - Transition metal catalyzed cross coupling (Continued...)
Link Heterocyclic Chemistry Lecture 21 - Dehydrogenative (Oxidative) cross coupling
Link Heterocyclic Chemistry Lecture 22 - Tert-amino effect in heterocycle synthesis
Link Heterocyclic Chemistry Lecture 23 - [4 plus 2] cycloaddition in heterocyclic chemistry
Link Heterocyclic Chemistry Lecture 24 - [4 plus 2] cycloaddition in heterocyclic chemistry (Continued...)
Link Heterocyclic Chemistry Lecture 25 - [3 plus 2] Cycloaddition in heterocyclic chemistry
Link Heterocyclic Chemistry Lecture 26 - Cycloaddition : Revisited
Link Heterocyclic Chemistry Lecture 27 - [4 plus 3] Cycloaddition
Link Heterocyclic Chemistry Lecture 28 - [5 plus 2] Cycloaddition
Link Heterocyclic Chemistry Lecture 29 - [2 plus 2 plus 2] Cycloaddition
Link Heterocyclic Chemistry Lecture 30 - Pyrrole Synthesis - I
Link Heterocyclic Chemistry Lecture 31 - Pyrrole Synthesis - II
Link Heterocyclic Chemistry Lecture 32 - Indole Synthesis - I
Link Heterocyclic Chemistry Lecture 33 - Indole Synthesis - II
Link Heterocyclic Chemistry Lecture 34 - Furan Synthesis
Link Heterocyclic Chemistry Lecture 35 - Thiophene Synthesis
Link Heterocyclic Chemistry Lecture 36 - Oxazole, Imidazole and Thiazole Synthesis
Link Heterocyclic Chemistry Lecture 37 - Pyridine Synthesis
Link Heterocyclic Chemistry Lecture 38 - Synthesis of Quinolines and Isoquinolines
Link Heterocyclic Chemistry Lecture 39 - Bycyclic Polyheteroatomic Heterocycles
Link Heterocyclic Chemistry Lecture 40 - Heterocyclic Rearrangements
Link Organic Photochemistry and Pericyclic Reactions Lecture 1 - Introduction to Organic Photochemistry
Link Organic Photochemistry and Pericyclic Reactions Lecture 2 - Introduction to Organic Photochemistry (Continued...)
Link Organic Photochemistry and Pericyclic Reactions Lecture 3 - Reactivity of n-pi*
Link Organic Photochemistry and Pericyclic Reactions Lecture 4 - α - cleavage - I
Link Organic Photochemistry and Pericyclic Reactions Lecture 5 - α - cleavage - II
Link Organic Photochemistry and Pericyclic Reactions Lecture 6 - α - cleavage - III
Link Organic Photochemistry and Pericyclic Reactions Lecture 7 - β - cleavage
Link Organic Photochemistry and Pericyclic Reactions Lecture 8 - Intramolecular Hydrogen Abstraction - I
Link Organic Photochemistry and Pericyclic Reactions Lecture 9 - Intramolecular Hydrogen Abstraction - II
Link Organic Photochemistry and Pericyclic Reactions Lecture 10 - Intramolecular Hydrogen Abstraction - III
Link Organic Photochemistry and Pericyclic Reactions Lecture 11 - Intramolecular Hydrogen Abstraction
Link Organic Photochemistry and Pericyclic Reactions Lecture 12 - Addition to Π - System
Link Organic Photochemistry and Pericyclic Reactions Lecture 13 - Intramolecular Paterno-Buchi Reaction
Link Organic Photochemistry and Pericyclic Reactions Lecture 14 - Energy of Electron Transfer Reaction
Link Organic Photochemistry and Pericyclic Reactions Lecture 15 - Reactivity of Π - Π*
Link Organic Photochemistry and Pericyclic Reactions Lecture 16 - Addition Reaction of Π - Π*
Link Organic Photochemistry and Pericyclic Reactions Lecture 17 - Addition Reaction of Π - Π* (Continued...)
Link Organic Photochemistry and Pericyclic Reactions Lecture 18 - Di-Pi Methane Rearrangement
Link Organic Photochemistry and Pericyclic Reactions Lecture 19 - Photochemistry of Cyclohexanone
Link Organic Photochemistry and Pericyclic Reactions Lecture 20 - Singlet Oxygen Chemistry
Link Organic Photochemistry and Pericyclic Reactions Lecture 21 - Carbenes and Nitrenes
Link Organic Photochemistry and Pericyclic Reactions Lecture 22 - Remote Functionalisation
Link Organic Photochemistry and Pericyclic Reactions Lecture 23 - Introduction to Pericyclic Reaction
Link Organic Photochemistry and Pericyclic Reactions Lecture 24 - Sigmatropic Reactions - I
Link Organic Photochemistry and Pericyclic Reactions Lecture 25 - Sigmatropic Reactions - II
Link Organic Photochemistry and Pericyclic Reactions Lecture 26 - Sigmatropic Reactions - III
Link Organic Photochemistry and Pericyclic Reactions Lecture 27 - Cycloaddition Reactions - I
Link Organic Photochemistry and Pericyclic Reactions Lecture 28 - Cycloaddition Reactions - II
Link Organic Photochemistry and Pericyclic Reactions Lecture 29 - Cycloaddition - Diels-Alder Reactions
Link Organic Photochemistry and Pericyclic Reactions Lecture 30 - Cycloaddition - Diels-Alder Reactions (Continued...)
Link Organic Photochemistry and Pericyclic Reactions Lecture 31 - Cycloaddition - Ene Reactions
Link Organic Photochemistry and Pericyclic Reactions Lecture 32 - 1,3 Dipolar Cycloaddition - I
Link Organic Photochemistry and Pericyclic Reactions Lecture 33 - 1,3 Dipolar Cycloaddition - II
Link Organic Photochemistry and Pericyclic Reactions Lecture 34 - Electrocyclic Reaction - I
Link Organic Photochemistry and Pericyclic Reactions Lecture 35 - Electrocyclic Reaction - II
Link Organic Photochemistry and Pericyclic Reactions Lecture 36 - Practice Problems in Pericyclic Reaction - I
Link Organic Photochemistry and Pericyclic Reactions Lecture 37 - Practice Problems in Pericyclic Reaction - II
Link Organic Photochemistry and Pericyclic Reactions Lecture 38 - Practice Problems in Pericyclic Reaction - III
Link Organic Photochemistry and Pericyclic Reactions Lecture 39 - Chelotropic Reaction
Link Organic Photochemistry and Pericyclic Reactions Lecture 40 - Application of Photochemistry
Link Polymer Chemistry Lecture 1 - Introduction to Polymers
Link Polymer Chemistry Lecture 2 - Introduction to Polymers (Continued...)
Link Polymer Chemistry Lecture 3 - Introduction to Polymers (Continued...)
Link Polymer Chemistry Lecture 4 - Step - growth Polymerization
Link Polymer Chemistry Lecture 5 - Step - growth Polymerization (Continued...)
Link Polymer Chemistry Lecture 6 - Step - growth Polymerization (Continued...)
Link Polymer Chemistry Lecture 7 - Step - growth Polymerization (Continued...)
Link Polymer Chemistry Lecture 8 - Step - growth Polymerization (Continued...)
Link Polymer Chemistry Lecture 9 - Radical Chain Polymerization
Link Polymer Chemistry Lecture 10 - Radical Chain Polymerization (Continued...)
Link Polymer Chemistry Lecture 11 - Radical Chain Polymerization (Continued...)
Link Polymer Chemistry Lecture 12 - Radical Chain Polymerization (Continued...)
Link Polymer Chemistry Lecture 13 - Radical Chain Polymerization (Continued...)
Link Polymer Chemistry Lecture 14 - Radical Chain Polymerization (Continued...)
Link Polymer Chemistry Lecture 15 - Radical Chain Polymerization (Continued...)
Link Polymer Chemistry Lecture 16 - Radical Chain Polymerization (Continued...)
Link Polymer Chemistry Lecture 17 - Ionic Chain Polymerization
Link Polymer Chemistry Lecture 18 - Ionic Chain Polymerization (Continued...)
Link Polymer Chemistry Lecture 19 - Ionic Chain Polymerization (Continued...) and Chain Copolymerization
Link Polymer Chemistry Lecture 20 - Chain Copolymerization (Continued...)
Link Polymer Chemistry Lecture 21 - Chain Copolymerization (Continued...)
Link Polymer Chemistry Lecture 22 - Chain Copolymerization (Continued...) and Ring Opening Polymerization
Link Polymer Chemistry Lecture 23 - Polymer Stereochemistry and Coordination Polymerization
Link Polymer Chemistry Lecture 24 - Polymer Stereochemistry and Coordination Polymerization (Continued...)
Link Polymer Chemistry Lecture 25 - Polymer Solutions
Link Polymer Chemistry Lecture 26 - Polymer Solutions (Continued...)
Link Polymer Chemistry Lecture 27 - Polymer Solutions (Continued...)
Link Polymer Chemistry Lecture 28 - Polymer Solutions (Continued...) and Chain Dimensions
Link Polymer Chemistry Lecture 29 - Chain Dimensions (Continued...) and Frictional Properties of Solution
Link Polymer Chemistry Lecture 30 - Frictional Properties of Solutions (Continued...) and Determination of Molecular Weight
Link Polymer Chemistry Lecture 31 - Determination of Molecular Weight of Polymers (Continued...)
Link Polymer Chemistry Lecture 32 - Determination of Molecular Weight of Polymers (Continued...)
Link Polymer Chemistry Lecture 33 - Determination of Molecular Weight of Polymers (Continued...)
Link Polymer Chemistry Lecture 34 - Structural Analysis of Polymers by Spectroscopic Methods
Link Polymer Chemistry Lecture 35 - Amorphous and Crystalline State : Tg and Tm
Link Polymer Chemistry Lecture 36 - Amorphous and Crystalline State : Tg and Tm (Continued...)
Link Polymer Chemistry Lecture 37 - Polymer Properties and Evaluation : Mechanical Properties
Link Polymer Chemistry Lecture 38 - Polymer Properties and Evaluation : Mechanical Properties (Continued...) and Other Properties
Link Polymer Chemistry Lecture 39 - Other Properties (Continued...) and Polymer Additives
Link Polymer Chemistry Lecture 40 - Polymer Additives (Continued...)
Link Polymer Chemistry Lecture 41 - Polymer Additives (Continued...), Blends, Concluding Remarks
Link Rate processes Lecture 1 - Rate Processes
Link Rate processes Lecture 2 - Reaction Rates and Rate Laws
Link Rate processes Lecture 3 - Effect of Temperature on Reaction Rate
Link Rate processes Lecture 4 - Effect of Temperature on Reaction Rate (Continued...)
Link Rate processes Lecture 5 - Complex Reaction
Link Rate processes Lecture 6 - Complex Reaction (Continued...)
Link Rate processes Lecture 7 - Complex Reaction (Continued...)
Link Rate processes Lecture 8 - Complex Reaction (Continued...)
Link Rate processes Lecture 9 - Theories of Reaction Rate
Link Rate processes Lecture 10 - Theories of Reaction Rate (Continued...)
Link Rate processes Lecture 11 - Theories of Reaction Rate (Continued...)
Link Rate processes Lecture 12 - Theories of Reaction Rate (Continued...)
Link Rate processes Lecture 13 - Theories of Reaction Rate (Continued...)
Link Rate processes Lecture 14 - Kinetics of Some Specific Reactions
Link Rate processes Lecture 15 - Kinetics of Some Specific Reactions (Continued...)
Link Rate processes Lecture 16 - Enzyme Inhibition
Link Rate processes Lecture 17 - Oscillatory Reactions
Link Rate processes Lecture 18 - Acid Base Catalysis
Link Rate processes Lecture 19 - Acid Base Catalysis (Continued...)
Link Rate processes Lecture 20 - Kinetic Isotope Effects
Link Rate processes Lecture 21 - Fast Reactions
Link Rate processes Lecture 22 - Fast Reactions (Continued...)
Link Rate processes Lecture 23 - Magneto Kinetics
Link Rate processes Lecture 24 - Reactions in Solutions
Link Rate processes Lecture 25 - Reactions in Solutions (Continued...)
Link Rate processes Lecture 26 - Kinetics at Electrodes
Link Rate processes Lecture 27 - Kinetics at Electrodes (Continued...)
Link Rate processes Lecture 28 - Ultrafast Process
Link Rate processes Lecture 29 - Ultrafast Process (Continued...)
Link Rate processes Lecture 30 - Ultrafast Process (Continued...)
Link Rate processes Lecture 31 - Reaction Dynamics
Link Rate processes Lecture 32 - Reaction Dynamics (Continued...)
Link Rate processes Lecture 33 - Reaction Dynamics (Continued...)
Link Rate processes Lecture 34 - Reaction Dynamics : Scattering
Link Rate processes Lecture 35 - Reaction Dynamics : Scattering (Continued...)
Link Rate processes Lecture 36 - Reaction Dynamics : Controlling Reagents etc
Link Rate processes Lecture 37 - Reaction Dynamics : Controlling Reagents etc (Continued...)
Link Rate processes Lecture 38 - Reaction Dynamics : Controlling Reagents etc (Continued...)
Link Rate processes Lecture 39 - Reaction Dynamics : Concluding
Link Rate processes Lecture 40 - Concluding Remarks
Link NOC:Biochemistry Lecture 1 - Amino Acid - I
Link NOC:Biochemistry Lecture 2 - Amino Acid - II
Link NOC:Biochemistry Lecture 3 - Protein Structure - I
Link NOC:Biochemistry Lecture 4 - Protein Structure - II
Link NOC:Biochemistry Lecture 5 - Protein Structure - III
Link NOC:Biochemistry Lecture 6 - Protein Structure - IV
Link NOC:Biochemistry Lecture 7 - Enzymes - I
Link NOC:Biochemistry Lecture 8 - Enzymes - II
Link NOC:Biochemistry Lecture 9 - Enzymes - III
Link NOC:Biochemistry Lecture 10 - Enzyme Mechanisms - I
Link NOC:Biochemistry Lecture 11 - Enzyme Mechanisms - II
Link NOC:Biochemistry Lecture 12 - Myoglobin and Hemoglobin
Link NOC:Biochemistry Lecture 13 - Lipids and Membranes - I
Link NOC:Biochemistry Lecture 14 - Lipids and Membranes - II
Link NOC:Biochemistry Lecture 15 - Membrane Transport
Link NOC:Biochemistry Lecture 16 - Nucleic Acids - I
Link NOC:Biochemistry Lecture 17 - Nucleic Acids - II
Link NOC:Biochemistry Lecture 18 - Nucleic Acids - III
Link NOC:Biochemistry Lecture 19 - Vitamins and Coenzymes - I
Link NOC:Biochemistry Lecture 20 - Vitamins and Coenzymes - II
Link NOC:Biochemistry Lecture 21 - Carbohydrates - I
Link NOC:Biochemistry Lecture 22 - Carbohydrates - II
Link NOC:Biochemistry Lecture 23 - Bioenergetics - I
Link NOC:Biochemistry Lecture 24 - Bioenergetics - II
Link NOC:Biochemistry Lecture 25 - Metabolism - I
Link NOC:Biochemistry Lecture 26 - Metabolism - II
Link NOC:Biochemistry Lecture 27 - Metabolism - III
Link NOC:Analytical Chemistry Lecture 1 - Chemicals and Materials Analysis
Link NOC:Analytical Chemistry Lecture 2 - Methods
Link NOC:Analytical Chemistry Lecture 3 - Methods (Continued...)
Link NOC:Analytical Chemistry Lecture 4 - Methods (Continued...)
Link NOC:Analytical Chemistry Lecture 5 - Methods (Continued...)
Link NOC:Analytical Chemistry Lecture 6 - Role of Analytical Chemistry
Link NOC:Analytical Chemistry Lecture 7 - Techniques, Wet Ashing
Link NOC:Analytical Chemistry Lecture 8 - Apparatus and Weighing
Link NOC:Analytical Chemistry Lecture 9 - Filtration, Ignition
Link NOC:Analytical Chemistry Lecture 10 - Crucibles, Filter Papers and their Uses
Link NOC:Analytical Chemistry Lecture 11 - Chemical Equilibria
Link NOC:Analytical Chemistry Lecture 12 - Chemical Equilibria (Continued...)
Link NOC:Analytical Chemistry Lecture 13 - Chemical Equilibria (Continued...)
Link NOC:Analytical Chemistry Lecture 14 - Chemical Equilibria (Continued...)
Link NOC:Analytical Chemistry Lecture 15 - Chemical Equilibria (Continued...)
Link NOC:Analytical Chemistry Lecture 16 - Spectrochemic Methods - I
Link NOC:Analytical Chemistry Lecture 17 - Spectrochemic Methods - I (Continued...)
Link NOC:Analytical Chemistry Lecture 18 - Spectrochemic Methods - I (Continued...)
Link NOC:Analytical Chemistry Lecture 19 - Spectrochemic Methods - I (Continued...)
Link NOC:Analytical Chemistry Lecture 20 - Spectrochemic Methods - I (Continued...)
Link NOC:Analytical Chemistry Lecture 21 - Spectrochemical Methods - II
Link NOC:Analytical Chemistry Lecture 22 - Spectrochemical Methods - II (Continued...)
Link NOC:Analytical Chemistry Lecture 23 - Spectrochemical Methods - III (Continued...)
Link NOC:Analytical Chemistry Lecture 24 - Spectrochemical Methods - IV (Continued...)
Link NOC:Analytical Chemistry Lecture 25 - Spectrochemical Methods - V (Continued...)
Link NOC:Analytical Chemistry Lecture 26 - Spectrochemical Methods - III
Link NOC:Analytical Chemistry Lecture 27 - Spectrochemical Methods - III (Continued...)
Link NOC:Analytical Chemistry Lecture 28 - Spectrochemical Methods - III (Continued...)
Link NOC:Analytical Chemistry Lecture 29 - Spectrochemical Methods - III (Continued...)
Link NOC:Analytical Chemistry Lecture 30 - Spectrochemical Methods - III (Continued...)
Link NOC:Analytical Chemistry Lecture 31 - Thermal Methods of Analysis - I
Link NOC:Analytical Chemistry Lecture 32 - Thermal Methods of Analysis - I (Continued...)
Link NOC:Analytical Chemistry Lecture 33 - Thermal Methods of Analysis - I (Continued...)
Link NOC:Analytical Chemistry Lecture 34 - Thermal Methods of Analysis - I (Continued...)
Link NOC:Analytical Chemistry Lecture 35 - Thermal Methods of Analysis - I (Continued...)
Link NOC:Analytical Chemistry Lecture 36 - Thermal Methods of Analysis - II
Link NOC:Analytical Chemistry Lecture 37 - Thermal Methods of Analysis - II (Continued...)
Link NOC:Analytical Chemistry Lecture 38 - Thermal Methods of Analysis - II (Continued...)
Link NOC:Analytical Chemistry Lecture 39 - Thermal Methods of Analysis - II (Continued...)
Link NOC:Analytical Chemistry Lecture 40 - Thermal Methods of Analysis - II (Continued...)
Link NOC:Analytical Chemistry Lecture 41 - Electrochemical Methods - I
Link NOC:Analytical Chemistry Lecture 42 - Electrochemical Methods - I (Continued...)
Link NOC:Analytical Chemistry Lecture 43 - Electrochemical Methods - I (Continued...)
Link NOC:Analytical Chemistry Lecture 44 - Electrochemical Methods - I (Continued...)
Link NOC:Analytical Chemistry Lecture 45 - Electrochemical Methods - I (Continued...):
Link NOC:Analytical Chemistry Lecture 46 - Electrochemical Methods - II
Link NOC:Analytical Chemistry Lecture 47 - Electrochemical Methods - II (Continued...)
Link NOC:Analytical Chemistry Lecture 48 - Electrochemical Methods - II (Continued...)
Link NOC:Analytical Chemistry Lecture 49 - Electrochemical Methods - II (Continued...)
Link NOC:Analytical Chemistry Lecture 50 - Electrochemical Methods - II (Continued...)
Link NOC:Analytical Chemistry Lecture 51 - Electrochemical Methods - III
Link NOC:Analytical Chemistry Lecture 52 - Electrochemical Methods - III (Continued...)
Link NOC:Analytical Chemistry Lecture 53 - Electrochemical Methods - III (Continued...)
Link NOC:Analytical Chemistry Lecture 54 - Electrochemical Methods - III (Continued...)
Link NOC:Analytical Chemistry Lecture 55 - Electrochemical Methods - III (Continued...)
Link NOC:Analytical Chemistry Lecture 56 - Applications
Link NOC:Analytical Chemistry Lecture 57 - Applications (Continued...)
Link NOC:Analytical Chemistry Lecture 58 - Applications (Continued...)
Link NOC:Analytical Chemistry Lecture 59 - Applications (Continued...)
Link NOC:Analytical Chemistry Lecture 60 - Applications (Continued...)
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 1 - Introduction
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 2 - Definition
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 3 - Classification of Ligands - I
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 4 - Classification of Ligands - II
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 5 - Ligands- III and Nomenclature - I
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 6 - Nomenclature - II
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 7 - Coordination Number - I
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 8 - Coordination Number - II
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 9 - Coordination Number - III
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 10 - Coordination Number - IV
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 11 - Isomerism - I
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 12 - Isomerism - II
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 13 - Co-ordination Equilibria - I
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 14 - Co-ordination Equilibria - II
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 15 - Bonding in Complexes - I
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 16 - Bonding in Complexes - II
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 17 - Bonding in Complexes - III
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 18 - Bonding in Complexes - IV
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 19 - Jahn - Teller Effect
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 20 - Spin Crossover and Colour
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 21 - Optical Spectra
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 22 - d-d Transitions
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 23 - Charge Transfer
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 24 - Orgel Diagram
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 25 - Tanabe Sugano Diagram
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 26 - MLCT Transitions
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 27 - Application of CFT
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 28 - Spinels
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 29 - Magnetochemistry
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 30 - Magnetic Properties
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 31 - Magnetic Measurements
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 32 - Ligand Field Theory
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 33 - Sigma Orbitals
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 34 - Pi Orbitals
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 35 - Reaction Mechanism - I
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 36 - Reaction Mechanism - II
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 37 - Reaction Mechanism - III
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 38 - Reaction Mechanism - IV
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 39 - Reaction Mechanism - V
Link NOC:Co-ordination Chemistry (Chemistry of Transition Elements) Lecture 40 - Biological Inorganic Chemistry
Link NOC:Stereochemistry Lecture 1 - Constitution and Configuration
Link NOC:Stereochemistry Lecture 2 - Chirality, Symmetry Elements
Link NOC:Stereochemistry Lecture 3 - Project Ion Formulae Rules for Drawing
Link NOC:Stereochemistry Lecture 4 - Project Ion Formulae Rules for Drawing
Link NOC:Stereochemistry Lecture 5 - Newmann Projection, Saw Horse Projection, Wedge Formula
Link NOC:Stereochemistry Lecture 6 - Chirotopicity and Stereogenicity
Link NOC:Stereochemistry Lecture 7 - Absolute Configuration
Link NOC:Stereochemistry Lecture 8 - Absolute Configuration (Continued...)
Link NOC:Stereochemistry Lecture 9 - Problems on the above topics
Link NOC:Stereochemistry Lecture 10 - Topicity
Link NOC:Stereochemistry Lecture 11 - Axial Chirality in Allenes, Biphenyls
Link NOC:Stereochemistry Lecture 12 - Relative Configuration, Prochiral Faces and Prochiral Centres
Link NOC:Stereochemistry Lecture 13 - Chirality in Heteroatom Systems
Link NOC:Stereochemistry Lecture 14 - Conformations and Conformers
Link NOC:Stereochemistry Lecture 15 - Conformational Analysis of Acyclic Molecules
Link NOC:Stereochemistry Lecture 16 - Conformational Analysis of Acyclic Molecules (Continued...)
Link NOC:Stereochemistry Lecture 17 - Conformations of Acyclic Molecues Containing Heteroatoms
Link NOC:Stereochemistry Lecture 18 - Conformations of Cyclic Systems
Link NOC:Stereochemistry Lecture 19 - Conformations of Cyclic Systems (Continued...)
Link NOC:Stereochemistry Lecture 20 - Conformation of Cyclobutane and Cyclopentane
Link NOC:Stereochemistry Lecture 21 - Conformation of Cyclohexane
Link NOC:Stereochemistry Lecture 22 - Energy Changes During Flipping
Link NOC:Stereochemistry Lecture 23 - Energy Comparison between Chair and Boat Conformations
Link NOC:Stereochemistry Lecture 24 - Conformational Analysis of Substituted Cyclohexanes
Link NOC:Stereochemistry Lecture 25 - Conformational Analysis of Substituted Cyclohexanes (Continued...)
Link NOC:Stereochemistry Lecture 26 - Conformational Analysis of Substituted Cyclohexanes (Continued...)
Link NOC:Stereochemistry Lecture 27 - Conformational Analysis of Substituted Cyclohexanes (Continued...)
Link NOC:Stereochemistry Lecture 28 - Conformational Analysis of Systems with Preference for Axial Groups
Link NOC:Stereochemistry Lecture 29 - Conformation and Reactivity
Link NOC:Stereochemistry Lecture 30 - Conformation and Reactivity (Continued...)
Link NOC:Stereochemistry Lecture 31 - Conformation and Reactivity (Continued...)
Link NOC:Stereochemistry Lecture 32 - Stereoelectronic Effects
Link NOC:Stereochemistry Lecture 33 - Stereoelectronic Effects (Continued...)
Link NOC:Stereochemistry Lecture 34 - Substitution and Elimination in Cyclohexane Systems
Link NOC:Stereochemistry Lecture 35 - Stereospecific and Stereoselective Reactions and Asymmetric Synthesis (Elementary Idea)
Link NOC:Stereochemistry Lecture 36 - Asymmetric Induction: Nucleophilic Addition to Chiral Carbonyl Compounds
Link NOC:Stereochemistry Lecture 37 - Asymmetric Induction: Nucleophilic Addition to Chiral Carbonyl Compounds (Continued...)
Link NOC:Stereochemistry Lecture 38 - Asymmetric Induction (Continued...)
Link NOC:Stereochemistry Lecture 39 - Facial Selectivity and Examples of Asymmetric Synthesis
Link NOC:Stereochemistry Lecture 40 - Revisiting the Contents Covered
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 1 - Introductory Remarks
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 2 - Introductory remarks (Continued...)
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 3 - Introductory remarks and some rapid fire quiz
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 4 - Retro Quiz based on simple Transformation
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 5 - Transformation based strategy for a given target
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 6 - Tf/Fg/SM based strategy and its exploratioin
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 7 - Tf/SM/Fg based approaches to solve some basic problems
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 8 - Tf/SM/Fg based strategy and its exploration
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 9 - Tf/SM/Fg based strategy and its exploration for some simple target molecules
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 10 - Tf/SM/Fg based strategy and its exploration
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 11 - Tf/SM/Fg based strategies and its exploration
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 12 - Tf/Fg/SM based strategies and its exploration
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 13 - Tf/Fg/SM based approaches and its exploration
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 14 - Tf/Fg/SM based strategies and its exploration
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 15 - Multiple Tf based strategy for small molecule disconnection
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 16 - Multiple Tf based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 17 - Specific Tf such as Barton's nitrile ester photolysis
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 18 - Specific transformation
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 19 - Selective transformations
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 20 - Functional Group (Fg) based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 21 - Functional group based strategy
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 22 - Fg based strategy
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 23 - Fg based strategy
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 24 - Fg based strategy based on protecting groups
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 25 - Fg based strategy
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 26 - Protecting group based strategic disconnection
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 27 - Fg group based strategy
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 28 - Fg based strategy
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 29 - Fg based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 30 - Fg based strategy
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 31 - Fg based strategy
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 32 - Fg based strategy
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 33 - Starting material (SM) based strategy
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 34 - Fg/Tf/SM based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 35 - Fg/Tf/SM based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 36 - Fg/Tf/SM based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 37 - Fg based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 38 - Fg based strategies in combination with SM and Tf
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 39 - Fg/SM/Tf based combined strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 40 - Fg/SM/Tf based combined strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 41 - Fg based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 42 - Fg based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 43 - Symmetry based strategy
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 44 - Symmetry based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 45 - Symmetry based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 46 - Symmetry based strategy
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 47 - Symmetry based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 48 - Symmetry based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 49 - Topological based strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 50 - Topological strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 51 - Topological strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 52 - Stereochemical strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 53 - Stereochemical strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 54 - Stereochemical strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 55 - Stereochemical Strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 56 - Stereochemical strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 57 - Stereochemical strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 58 - Stereochemical strategies
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 59 - Synthon concept revisited
Link NOC:A Study Guide in Organic Retrosynthesis - Problem Solving Approach Lecture 60 - Concluding remarks
Link NOC:Introduction to Molecular Thermodynamics Lecture 1 - Review of Classical Thermodynamics - Part I
Link NOC:Introduction to Molecular Thermodynamics Lecture 2 - Review of Classical Thermodynamics - Part II
Link NOC:Introduction to Molecular Thermodynamics Lecture 3 - Thermodynamic potentials - Part 1
Link NOC:Introduction to Molecular Thermodynamics Lecture 4 - Thermodynamic potentials - Part 2
Link NOC:Introduction to Molecular Thermodynamics Lecture 5 - Microstates of a system
Link NOC:Introduction to Molecular Thermodynamics Lecture 6 - Microstates of a System (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 7 - Microstates of a system (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 8 - Microstates of a system (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 9 - Microstates of a system
Link NOC:Introduction to Molecular Thermodynamics Lecture 10 - Microstates of a system
Link NOC:Introduction to Molecular Thermodynamics Lecture 11 - Microstates of a system (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 12 - Microstates of a system (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 13 - Microstates of a System (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 14 - Fundamentals of Statistical Mechanics
Link NOC:Introduction to Molecular Thermodynamics Lecture 15 - Statistical Ensembles
Link NOC:Introduction to Molecular Thermodynamics Lecture 16 - Microstates of a system
Link NOC:Introduction to Molecular Thermodynamics Lecture 17 - Canonical ensemble - Part I
Link NOC:Introduction to Molecular Thermodynamics Lecture 18 - Canonical Ensemble - Part I (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 19 - Canonical Ensemble - Part II
Link NOC:Introduction to Molecular Thermodynamics Lecture 20 - Canonical Ensemble - Part III
Link NOC:Introduction to Molecular Thermodynamics Lecture 21 - Ideal gas
Link NOC:Introduction to Molecular Thermodynamics Lecture 22 - Ideal gases (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 23 - Ideal gases (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 24 - Ideal gases (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 25 - Statistical thermodynamics of ideal gases (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 26 - Statistical Thermodynamics of ideal gases (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 27 - Statistical thermodynamics of ideal gases (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 28 - Statistical thermodynamics of ideal gases (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 29 - Statistical thermodynamics of ideal gases (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 30 - Statistical thermodynamics of diatomic ideal gases
Link NOC:Introduction to Molecular Thermodynamics Lecture 31 - Statistical thermodynamics of ideal gas
Link NOC:Introduction to Molecular Thermodynamics Lecture 32 - Chemical reaction equilibrium
Link NOC:Introduction to Molecular Thermodynamics Lecture 33 - Specific heat of solids
Link NOC:Introduction to Molecular Thermodynamics Lecture 34 - Application of Molecular Thermodynamics
Link NOC:Introduction to Molecular Thermodynamics Lecture 35 - Introduction to classical statistical mechanics
Link NOC:Introduction to Molecular Thermodynamics Lecture 36 - Introduction to classical statistical mechanics (Continued...)
Link NOC:Introduction to Molecular Thermodynamics Lecture 37 - Classical Statistical Mechanics
Link NOC:Introduction to Molecular Thermodynamics Lecture 38 - Classical Statistical Mechanics
Link NOC:Introduction to Molecular Thermodynamics Lecture 39 - Classical Statistical Mechanics
Link NOC:Introduction to Molecular Thermodynamics Lecture 40 - Rate of Chemical Reaction
Link NOC:Molecules in Motion Lecture 1 - Kinetic theory of gases
Link NOC:Molecules in Motion Lecture 2 - Kinetic theory of gases (Continued...)
Link NOC:Molecules in Motion Lecture 3 - Kinetic theory of gases (Continued...)
Link NOC:Molecules in Motion Lecture 4 - Kinetic theory of gases (Continued...)
Link NOC:Molecules in Motion Lecture 5 - Kinetic theory of gases (Continued...)
Link NOC:Molecules in Motion Lecture 6 - Kinetic theory of gases (Continued...)
Link NOC:Molecules in Motion Lecture 7 - Kinetic theory of gases (Continued...)
Link NOC:Molecules in Motion Lecture 8 - Kinetic theory of gases (Continued...)
Link NOC:Molecules in Motion Lecture 9 - Kinetic theory of gases (Continued...)
Link NOC:Molecules in Motion Lecture 10 - Kinetic theory of gases (Continued...)
Link NOC:Molecules in Motion Lecture 11 - Transport properties
Link NOC:Molecules in Motion Lecture 12 - Transport properties (Continued...)
Link NOC:Molecules in Motion Lecture 13 - Transport properties of gases
Link NOC:Molecules in Motion Lecture 14 - Molecular motion in Liquids
Link NOC:Molecules in Motion Lecture 15 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 16 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 17 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 18 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 19 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 20 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 21 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 22 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 23 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 24 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 25 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 26 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 27 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 28 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 29 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 30 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 31 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 32 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 33 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 34 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 35 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 36 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 37 - Molecular motion in Liquids (Continued...)
Link NOC:Molecules in Motion Lecture 38 - Molecular motion in gases
Link NOC:Molecules in Motion Lecture 39 - Molecular motion in gases
Link NOC:Molecules in Motion Lecture 40 - Molecular motion in gases
Link NOC:Experimental Biochemistry Lecture 1 - Introduction
Link NOC:Experimental Biochemistry Lecture 2 - Buffers
Link NOC:Experimental Biochemistry Lecture 3 - Introduction to Biochemistry Laboratory Equipments and Safety Measures
Link NOC:Experimental Biochemistry Lecture 4 - Practical Aspects of Making Buffer
Link NOC:Experimental Biochemistry Lecture 5 - Making Tris Buffer (pH=8.2)
Link NOC:Experimental Biochemistry Lecture 6 - Making Phosphate Buffer (100mM)
Link NOC:Experimental Biochemistry Lecture 7 - Amino Acids and Their Properties
Link NOC:Experimental Biochemistry Lecture 8 - Amino Acid Titrations
Link NOC:Experimental Biochemistry Lecture 9 - pI Determination of Glycine
Link NOC:Experimental Biochemistry Lecture 10 - pI Determination of Lysine
Link NOC:Experimental Biochemistry Lecture 11 - Summary
Link NOC:Experimental Biochemistry Lecture 12 - UV and Visible Spectroscopy
Link NOC:Experimental Biochemistry Lecture 13 - Fluorescence Spectroscopy
Link NOC:Experimental Biochemistry Lecture 14 - UV/Visible Spectra of Amino Acids and Proteins
Link NOC:Experimental Biochemistry Lecture 15 - Fluorescence Spectra of Amino Acids and proteins
Link NOC:Experimental Biochemistry Lecture 16 - Spectroscopic Techniques Summary
Link NOC:Experimental Biochemistry Lecture 17 - Protein Folding and Denaturation - I
Link NOC:Experimental Biochemistry Lecture 18 - Protein Folding and Denaturation - II
Link NOC:Experimental Biochemistry Lecture 19 - Urea denaturation of HSA studied by UV/Vis absorbance
Link NOC:Experimental Biochemistry Lecture 20 - Temperature denaturation of HSA studied by UV/Vis absorbance
Link NOC:Experimental Biochemistry Lecture 21 - Denaturation of HSA by GdnHCl studied by Trp fluorescence
Link NOC:Experimental Biochemistry Lecture 22 - Protein Folding and Denaturation Summary
Link NOC:Experimental Biochemistry Lecture 23 - Chromatographic Techniques - I
Link NOC:Experimental Biochemistry Lecture 24 - Chromatographic Techniques - II
Link NOC:Experimental Biochemistry Lecture 25 - Protein Purification by Size Exclusion Chromatography (SEC)
Link NOC:Experimental Biochemistry Lecture 26 - Protein Purification by Affinity Chromatography
Link NOC:Experimental Biochemistry Lecture 27 - Gel Electrophoresis of DNA and Proteins - Part I
Link NOC:Experimental Biochemistry Lecture 28 - Gel Electrophoresis of DNA and Proteins - Part II
Link NOC:Experimental Biochemistry Lecture 29 - Gel Electrophoresis of DNA and Proteins - Part II
Link NOC:Experimental Biochemistry Lecture 30 - Isolation and Characterization of Proteins Part - I
Link NOC:Experimental Biochemistry Lecture 31 - Isolation and Characterization of Proteins Part - II
Link NOC:Experimental Biochemistry Lecture 32 - Isolation and Purification of Proteins
Link NOC:Experimental Biochemistry Lecture 33 - Quality and Quantity of the Isolated Protein
Link NOC:Experimental Biochemistry Lecture 34 - Enzyme Kinetics - I
Link NOC:Experimental Biochemistry Lecture 35 - Enzyme Kinetics - II
Link NOC:Experimental Biochemistry Lecture 36 - Enzyme Kinetics (by using enzyme from apple juice)
Link NOC:Experimental Biochemistry Lecture 37 - Enzyme Kinetics (by using enzyme from apple juice) (Continued...)
Link NOC:Experimental Biochemistry Lecture 38 - Isolation and Characterization of DNA Part - I
Link NOC:Experimental Biochemistry Lecture 39 - Isolation and Characterization of DNA Part - II
Link NOC:Experimental Biochemistry Lecture 40 - Bacterial Culture for Plasmid DNA Isolation
Link NOC:Experimental Biochemistry Lecture 41 - Isolation of Plasmid DNA
Link NOC:Experimental Biochemistry Lecture 42 - Isolation and Characterization of DNA Summary
Link NOC:Experimental Biochemistry Lecture 43 - Basics of rDNA Technology Part - I
Link NOC:Experimental Biochemistry Lecture 44 - Basics of rDNA Technology Part - II
Link NOC:Experimental Biochemistry Lecture 45 - Cloning : Polymerase Chain Reaction, Restriction Enzyme Digestion and Ligation
Link NOC:Experimental Biochemistry Lecture 46 - DNA Transformation
Link NOC:Experimental Biochemistry Lecture 47 - Protein-Ligand Interaction
Link NOC:Experimental Biochemistry Lecture 48 - Protein-Ligand Interaction (Continued...)
Link NOC:Experimental Biochemistry Lecture 49 - Interaction study of HSA protein with Curcumin and Gallic acid using UV-Vis spectroscopy
Link NOC:Experimental Biochemistry Lecture 50 - Interaction study of HSA protein with Circumin and Gallic acid using UV-Vis spectroscopy (Continued...)
Link NOC:Experimental Biochemistry Lecture 51 - Analysis of the Structure of Protein ligand complex
Link NOC:Experimental Biochemistry Lecture 52 - Immunoassay Techniques
Link NOC:Experimental Biochemistry Lecture 53 - Western Blotting Technique
Link NOC:Industrial Inorganic Chemistry Lecture 1 - Introduction
Link NOC:Industrial Inorganic Chemistry Lecture 2 - Importance of chemical industry, chemicals from materials
Link NOC:Industrial Inorganic Chemistry Lecture 3 - Bulk and commodity chemicals
Link NOC:Industrial Inorganic Chemistry Lecture 4 - Fine and speciality chemicals
Link NOC:Industrial Inorganic Chemistry Lecture 5 - Water
Link NOC:Industrial Inorganic Chemistry Lecture 6 - Hydrogen
Link NOC:Industrial Inorganic Chemistry Lecture 7 - Inorganic peroxide compounds
Link NOC:Industrial Inorganic Chemistry Lecture 8 - Nitrogen compounds
Link NOC:Industrial Inorganic Chemistry Lecture 9 - Chloramine and Hydroxylamine
Link NOC:Industrial Inorganic Chemistry Lecture 10 - Nitric acid, Ostwald process and uses
Link NOC:Industrial Inorganic Chemistry Lecture 11 - Phosphorus and its components
Link NOC:Industrial Inorganic Chemistry Lecture 12 - Phosphoric acid salts
Link NOC:Industrial Inorganic Chemistry Lecture 13 - Tetrapotassium diphosphate preparation
Link NOC:Industrial Inorganic Chemistry Lecture 14 - Hydroxy apatite
Link NOC:Industrial Inorganic Chemistry Lecture 15 - P4S10 and phosphide preparation
Link NOC:Industrial Inorganic Chemistry Lecture 16 - Sulfur and copper (1) phosphide
Link NOC:Industrial Inorganic Chemistry Lecture 17 - Sulfur compounds and sulfur from H2S and SO2
Link NOC:Industrial Inorganic Chemistry Lecture 18 - Sulfuric acid, catalyst and S2Cl2, applications
Link NOC:Industrial Inorganic Chemistry Lecture 19 - Sulfur dichloride, thionyl chloride
Link NOC:Industrial Inorganic Chemistry Lecture 20 - Thiosulfates and dithionite
Link NOC:Industrial Inorganic Chemistry Lecture 21 - Sodium hydroxyl methanesulfinate and hydrogen sulfide
Link NOC:Industrial Inorganic Chemistry Lecture 22 - Halogen and halogen compounds
Link NOC:Industrial Inorganic Chemistry Lecture 23 - Fluorine and inorganic fluorides
Link NOC:Industrial Inorganic Chemistry Lecture 24 - Hydrogen fluoride and aluminum fluoride
Link NOC:Industrial Inorganic Chemistry Lecture 25 - Cryolite and other industrially important fluoride salts
Link NOC:Industrial Inorganic Chemistry Lecture 26 - Electrochemical fluorination, sulfonyl fluorides
Link NOC:Industrial Inorganic Chemistry Lecture 27 - Chloralkali electrolysis
Link NOC:Industrial Inorganic Chemistry Lecture 28 - Ion conduction membrane in electrolysis
Link NOC:Industrial Inorganic Chemistry Lecture 29 - Hydrochloric acid manufacture
Link NOC:Industrial Inorganic Chemistry Lecture 30 - Bromine and bromine compounds
Link NOC:Industrial Inorganic Chemistry Lecture 31 - Hydrogen bromide and alkali bromates
Link NOC:Industrial Inorganic Chemistry Lecture 32 - Iodine and iodine compounds
Link NOC:Industrial Inorganic Chemistry Lecture 33 - Mineral fertilizers
Link NOC:Industrial Inorganic Chemistry Lecture 34 - Nitrogen fertilizer and Urea
Link NOC:Industrial Inorganic Chemistry Lecture 35 - Potassium fertilizer
Link NOC:Industrial Inorganic Chemistry Lecture 36 - Metals and their compounds: Lithium
Link NOC:Industrial Inorganic Chemistry Lecture 37 - Sodium and its compounds
Link NOC:Industrial Inorganic Chemistry Lecture 38 - Potassium and its compounds
Link NOC:Industrial Inorganic Chemistry Lecture 39 - Magnesium and its compounds
Link NOC:Industrial Inorganic Chemistry Lecture 40 - Calcium and its compounds
Link NOC:Industrial Inorganic Chemistry Lecture 41 - Barium and its compounds
Link NOC:Industrial Inorganic Chemistry Lecture 42 - Chromium and its compounds
Link NOC:Industrial Inorganic Chemistry Lecture 43 - Manganese and its industrially important compounds
Link NOC:Industrial Inorganic Chemistry Lecture 44 - Silicon and its compounds
Link NOC:Industrial Inorganic Chemistry Lecture 45 - Organosilicon compounds, organoalkoxysilanes
Link NOC:Industrial Inorganic Chemistry Lecture 46 - Organomercapto silanes and silicones
Link NOC:Industrial Inorganic Chemistry Lecture 47 - Silicone rubber
Link NOC:Industrial Inorganic Chemistry Lecture 48 - Inorganic solids: glass
Link NOC:Industrial Inorganic Chemistry Lecture 49 - Zeolites
Link NOC:Industrial Inorganic Chemistry Lecture 50 - Inorganic Fibres: asbestos, textile glass and optical fibres
Link NOC:Industrial Inorganic Chemistry Lecture 51 - Glass fibre production and construction materials
Link NOC:Industrial Inorganic Chemistry Lecture 52 - Ceramics and its manufacturing processes
Link NOC:Industrial Inorganic Chemistry Lecture 53 - Specialty ceramic products
Link NOC:Industrial Inorganic Chemistry Lecture 54 - Ferrites and porcelain enamel
Link NOC:Industrial Inorganic Chemistry Lecture 55 - Layers of enamelling
Link NOC:Industrial Inorganic Chemistry Lecture 56 - Carbon modifications: Glassy carbon, foamed carbon, carbon black
Link NOC:Industrial Inorganic Chemistry Lecture 57 - Activated carbon
Link NOC:Industrial Inorganic Chemistry Lecture 58 - Metallic hard materials: Carbides, borides, silicides
Link NOC:Industrial Inorganic Chemistry Lecture 59 - Fillers and inorganic pigments
Link NOC:Industrial Inorganic Chemistry Lecture 60 - Oxide pigments, luminescent pigments, corrosion protection pigments, magnetic pigments
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 1 - Introduction
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 2 - Structure and Geometry of Carbenes
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 3 - Structure and Geometry of Carbenes (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 4 - Generation of Carbene
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 5 - Generation of Carbene (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 6 - Generation of Carbene (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 7 - Reaction of Carbene
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 8 - Reaction of Carbene (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 9 - Reaction of Carbene (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 10 - Reaction of Carbene (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 11 - Reaction of Carbene (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 12 - Reaction of Carbene (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 13 - Reaction of Carbene (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 14 - Reaction of Carbene (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 15 - Reaction of Carbene (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 16 - Nitrene
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 17 - Nitrene (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 18 - Reaction of Nitrene
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 19 - Reaction of Nitrene (Continued...)
Link NOC:Reactive Intermediates Carbene and Nitrene Lecture 20 - Reaction of Nitrene (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 1 - A brief introduction to Molecules of Life: Structure of Amino acids and their various charged forms
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 2 - Biological Macromolecules and Small molecules: Importance and functions
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 3 - Amino Acids: The building block of proteins
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 4 - Amino acids: separation and detection, Electrophoresis and Ninhydrin reaction
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 5 - Method of determination of Amino acid sequence: primary structure of polypeptide/protein
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 6 - Selective peptide bond cleavage: Enzymatic and Non-enzymatic methods
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 7 - Peptide synthesis: Protecting groups for amine and carboxyl functionality
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 8 - Peptide synthesis (Continued...) Protection, coupling and deprotection method
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 9 - Recent development of coupling agents; Merrifield’s method of solid phase peptide synthesis
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 10 - Hierarchial structure of proteins: Secondary, tertiary and quaternary structure
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 11 - Ramachandran plot and protein purification techniques
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 12 - Protein purification techniques (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 13 - Introduction to Enzymes and its kinetics
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 14 - Enzyme catalysed reactions and introduction to catalytic activity of proteases
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 15 - Enzyme Kinetics (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 16 - Concept of Enzyme Inhibition
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 17 - Concept of Enzyme Inhibition (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 18 - Problems on Enzyme Kinetics and Enzyme Inhibition
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 19 - Synthetic Biology
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 20 - Synthetic Biology (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 21 - Synthetic Biology (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 22 - Nucleic Acid
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 23 - Nucleic Acid (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 24 - DNA sequencing method
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 25 - DNA sequencing method (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 26 - DNA sequencing method (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 27 - Synthesis of oligonucleotide
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 28 - Central dogma: DNA replication, transcription and translation
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 29 - Central dogma: DNA replication, transcription and translation (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 30 - Central dogma: DNA replication, transcription and translation (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 31 - Central dogma: DNA replication, transcription and translation (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 32 - Central dogma: DNA replication, transcription and translation (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 33 - Molecular Biology
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 34 - Molecular Biology (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 35 - Chemistry of cofactors/coenzymes
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 36 - Chemistry of cofactors/coenzymes (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 37 - Chemistry of cofactors/coenzymes (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 38 - Chemistry of cofactors/coenzymes (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 39 - Chemistry of cofactors/coenzymes (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 40 - Chemistry of cofactors/coenzymes (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 41 - Introduction to Drug Discovery Process
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 42 - Fundamental Principles of Drug Development Process
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 43 - Combinatorial chemistry
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 44 - Neurotransmitters
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 45 - Catechol amine based and GABA neurotransmitters
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 46 - Hypertension: humoral mechanism and renin/angiotensin system
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 47 - Inhibitor design of angiotensin converting enzyme
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 48 - Antimicrobial drugs
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 49 - Chemistry of penicillins
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 50 - Resistance to beta-lactam antibiotics
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 51 - Mechanistic studies of beta-lactamase
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 52 - Non beta-lactam antibiotics
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 53 - Mechanistic enzymology of Isopenicillin N synthase
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 54 - Polyketide Biosynthesis
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 55 - Biosynthesis of macrolide polyketides and introduction to virus
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 56 - Anti-viral drugs
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 57 - Cancer and Chemotherapy
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 58 - Anti-cancer drugs (Continued...)
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 59 - Aromatase inhibition and Anti-ulcer drugs
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 60 - Cholesterol lowering agents
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 61 - Cholesterol Biosynthesis
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 62 - Pharmakinetics and pharmadynamics
Link NOC:Organic Chemistry in Biology and Drug Development Lecture 63 - QSAR principles
Link NOC:Introduction to Polymer Science Lecture 1 - Importance of Polymer Science and Brief Historical background
Link NOC:Introduction to Polymer Science Lecture 2 - Definitions/Terminologies, Classifications
Link NOC:Introduction to Polymer Science Lecture 3 - Classifications, Nomenclature
Link NOC:Introduction to Polymer Science Lecture 4 - Classification by Polymerization Mechanism, Nomenclature
Link NOC:Introduction to Polymer Science Lecture 5 - Molecular Weight, Big Picture of Polymer Science, Common Polymers
Link NOC:Introduction to Polymer Science Lecture 6 - Examples of Step Polymers, Linear Step Polymerization
Link NOC:Introduction to Polymer Science Lecture 7 - Linear Step Polymerization: MW Control, MW Distribution, Kinetics
Link NOC:Introduction to Polymer Science Lecture 8 - Linear Step Polymerization: Kinetics (Continued...), Equilibrium Consideration, General Requirements for Achieving High MW; Non-linear Step Polymerization
Link NOC:Introduction to Polymer Science Lecture 9 - Linear Step Polymerization: Summary - General Requirement, Non-Linear Step Polymerization
Link NOC:Introduction to Polymer Science Lecture 10 - Types of Chain polymerization, Mechanism and Kinetics of Radical Chain Polymerization
Link NOC:Introduction to Polymer Science Lecture 11 - Kinetics of Radical Chain Polymerization (Continued...), Various Types of Initiators
Link NOC:Introduction to Polymer Science Lecture 12 - Thermal Initiation (Continued...), Molecular Weight and Kinetic Chain Length, Other Types of Radical Initiators, Transfer Reactions
Link NOC:Introduction to Polymer Science Lecture 13 - Transfer Reactions, Effect of Temperature on Rate and MW, MW Distribution, ceiling Temperature
Link NOC:Introduction to Polymer Science Lecture 14 - Energetics and Thermodynamics of Chain Polymerization, MW Distribution, Common Polymers
Link NOC:Introduction to Polymer Science Lecture 15 - Thermodynamics of Chain Polymerization, MW Distribution, Common Polymers
Link NOC:Introduction to Polymer Science Lecture 16 - Process Conditions, Emulsion Polymerization
Link NOC:Introduction to Polymer Science Lecture 17 - Emulsion Polymerization (Continued...), Common Polymers by Radical Chain Polymerization, RDRP
Link NOC:Introduction to Polymer Science Lecture 18 - Reversible - Deactivation Radical Polymerizations (RDRP)
Link NOC:Introduction to Polymer Science Lecture 19 - RAFT Polymerization (Continued...), Ionic Polymerization
Link NOC:Introduction to Polymer Science Lecture 20 - Polymer Stereochemistry and Zeigler - Natta Coordination Polymerization
Link NOC:Introduction to Polymer Science Lecture 21 - Ring Opening Polymerization, Copolymers
Link NOC:Introduction to Polymer Science Lecture 22 - Copolymerization (Continued...)
Link NOC:Introduction to Polymer Science Lecture 23 - Polymers in Solution : Flory - Huggins Theory
Link NOC:Introduction to Polymer Science Lecture 24 - Polymers in Solution : Application of Flory - Huggins Theory
Link NOC:Introduction to Polymer Science Lecture 25 - Polymers in Solution : Solubility Parameter, Polymer Phase Separation and Fractionation
Link NOC:Introduction to Polymer Science Lecture 26 - Polymers Chain Dimensions
Link NOC:Introduction to Polymer Science Lecture 27 - Frictional Properties of Polymer Molecules in Dilute Solution, Determination of Polymer MW (Overview)
Link NOC:Introduction to Polymer Science Lecture 28 - Membrane Osmometry, End Group Analysis, Dilute Solution Viscometry
Link NOC:Introduction to Polymer Science Lecture 29 - Dilute Solution Viscometry, Light Scattering Techniques for MW
Link NOC:Introduction to Polymer Science Lecture 30 - Gel Permeation Chromatography
Link NOC:Introduction to Polymer Science Lecture 31 - Light Scattering Techniques for MW and Size Measurements (Continued...)
Link NOC:Introduction to Polymer Science Lecture 32 - Mass Spectroscopy of Polymers
Link NOC:Introduction to Polymer Science Lecture 33 - Polymer Processing
Link NOC:Introduction to Polymer Science Lecture 34 - Mechanical Properties, Amorphous State
Link NOC:Introduction to Polymer Science Lecture 35 - Thermal Properties: Amorphous State
Link NOC:Introduction to Polymer Science Lecture 36 - Thermal Properties: Crystalline State
Link NOC:Introduction to Polymer Science Lecture 37 - Thermal Properties: Factors Influencing Tm, Determination of Tg and Tm, Other Thermal Properties
Link NOC:Introduction to Polymer Science Lecture 38 - Thermomechanical Properties, Viscoelasticity
Link NOC:Introduction to Polymer Science Lecture 39 - Thermomechanical Properties, Viscoelasticity (Continued...)
Link NOC:Introduction to Polymer Science Lecture 40 - Optical, Electrical, Barrier Properties; Chemical Resistance and Weathering of Polymers
Link NOC:Introduction to Polymer Science Lecture 41 - Polymer Additives
Link NOC:Introduction to Polymer Science Lecture 42 - Polymer Blends, Concluding Remarks
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 1 - Introduction to structure and stereochemistry of organic molecules: salient features of symmetry elements; Role of principal axis, sigma plane, centre of symmetry, and alternating axis of symmetry in deciding chirality
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 2 - Introduction to point group notation, classification, symmetry number and order
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 3 - Examples of various point group notations, chiral and achiral point groups, examples of various point groups
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 4 - Solving problems on point groups (Cn, Cnv, Cnh, Dnd)
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 5 - Conformational Analysis of Perhydrophenanthrene
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 6 - Concept Clearing Session on Achiral Point Groups
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 7 - Axial, Planar and Helical Chirality, assignment of absolute configuration to such molecules
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 8 - Concept of pseudoasymmetry; Reflection variance/invariance problem; methods of nomenclature system
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 9 - Conformational analysis of bicyclic systems: the Decalins
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 10 - Conformational analysis of Perhydrophenanthrene
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 11 - Conformational analysis of Perhydroanthracene
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 12 - Revisiting conformational analysis of Perhydrophenanthrene
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 13 - Revisiting conformational analysis of Perhydroanthracene
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 14 - Introduction to Linear Polarized light and interaction with chiral materials; Circular Birefringence, Circular Dichroism
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 15 - ORD, CD and Cotton Effect (CE); Empirical rule to determine the sign of CE, 2-axial haloketone rule
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 16 - Octant rule: application to substituted cyclohexanone and decalone system
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 17 - Application of Octant rule to tricyclic system; drawing of octant projection
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 18 - Application of Octant rule to steroidal ketones; drawing of octant projection
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 19 - Stereoelectronic effects on conformation and reactivity
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 20 - Examples of anomeric effect and Stereoelectronic effect
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 21 - Baldwin rules
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 22 - Cyclization in enolic systems
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 23 - Problem solving on Baldwin rules
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 24 - Reactive Functionalities: Chemistry of Alkynes
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 25 - Reactive Functionalities: Chemistry of Alkynes (Continued...), arynes and enediynes
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 26 - Reactive Functionalities: Enediynes (Continued...), allenes and Ketenes
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 27 - Beta - Lactam Synthesis
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 28 - Chemistry of radicals
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 29 - Reactivity of radicals: Frontier orbital approach.
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 30 - Radical mediated C-C bond formation
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 31 - Radical mediated C-C bond formation (Continued...).
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 32 - Radical mediated decarboxylation and deoxygenation
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 33 - Dynamic Stereochemistry: Conformationally rigid and mobile systems
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 34 - Dynamic Stereochemistry: Conformational analysis of elimination and addition
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 35 - Dynamic Stereochemistry: Stereoselectivity in carbonyl reduction
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 36 - Dynamic Stereochemistry: Reactivity of unsaturated carbonyl and enolate systems
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 37 - Dynamic Stereochemistry: Enolate as nucleophile
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 38 - Dynamic Stereochemistry: stereochemical issues in cyclohexenone reduction and alpha-electrophilic substitution in carbonyls
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 39 - Dynamic Stereochemistry: Asymmetric aldol reactions
Link NOC:Structure, Stereochemistry and Reactivity of Organic Compounds and Intermediates: A Problem Solving Approach Lecture 40 - Dynamic Stereochemistry: Asymmetric aldol reaction (Continued...)
Link NOC:Approximate Methods in Quantum Chemistry Lecture 1 - Review of Quantum Chemistry
Link NOC:Approximate Methods in Quantum Chemistry Lecture 2 - Postulates of Quantum Mechanics - I
Link NOC:Approximate Methods in Quantum Chemistry Lecture 3 - Postulates of Quantum Mechanics - II
Link NOC:Approximate Methods in Quantum Chemistry Lecture 4 - Exactly Solvable Models - I
Link NOC:Approximate Methods in Quantum Chemistry Lecture 5 - Exactly Solvable Models - II
Link NOC:Approximate Methods in Quantum Chemistry Lecture 6 - Exactly Solvable Models - II (Continued...)
Link NOC:Approximate Methods in Quantum Chemistry Lecture 7 - Variational Principle - I
Link NOC:Approximate Methods in Quantum Chemistry Lecture 8 - Variational Principle - II
Link NOC:Approximate Methods in Quantum Chemistry Lecture 9 - Variational Method: Applications - I
Link NOC:Approximate Methods in Quantum Chemistry Lecture 10 - Linear Variational Method
Link NOC:Approximate Methods in Quantum Chemistry Lecture 11 - Applications of Linear Variational Method
Link NOC:Approximate Methods in Quantum Chemistry Lecture 12 - Variational Method in Chemical Bonding - I
Link NOC:Approximate Methods in Quantum Chemistry Lecture 13 - Variational Method in Chemical Bonding - II
Link NOC:Approximate Methods in Quantum Chemistry Lecture 14 - Variational Method in Chemical Bonding - III
Link NOC:Approximate Methods in Quantum Chemistry Lecture 15 - Molecular Orbital Treatment of Polyatomics
Link NOC:Approximate Methods in Quantum Chemistry Lecture 16 - Molecular Orbital Treatment of Polyatomics
Link NOC:Approximate Methods in Quantum Chemistry Lecture 17 - Perturbation Theory
Link NOC:Approximate Methods in Quantum Chemistry Lecture 18 - Examples of Perturbation Theory - I
Link NOC:Approximate Methods in Quantum Chemistry Lecture 19 - Examples of Perturbation Theory - II
Link NOC:Approximate Methods in Quantum Chemistry Lecture 20 - Molecular Response to Electric Field - I
Link NOC:Approximate Methods in Quantum Chemistry Lecture 21 - Molecular Response to Electric Field - II
Link NOC:Approximate Methods in Quantum Chemistry Lecture 22 - Degenerate Perturbation Theory
Link NOC:Approximate Methods in Quantum Chemistry Lecture 23 - Excited States of He Atom - I
Link NOC:Approximate Methods in Quantum Chemistry Lecture 24 - Excited States of He Atom - II
Link NOC:Approximate Methods in Quantum Chemistry Lecture 25 - Slater Determinants - I
Link NOC:Approximate Methods in Quantum Chemistry Lecture 26 - Slater Determinants - II
Link NOC:Approximate Methods in Quantum Chemistry Lecture 27 - Energy Expectation Value with Slater Determinants - I
Link NOC:Approximate Methods in Quantum Chemistry Lecture 28 - Energy Expectation Value with Slater Determinants - II
Link NOC:Approximate Methods in Quantum Chemistry Lecture 29 - Self-Consistent Field Method
Link NOC:Approximate Methods in Quantum Chemistry Lecture 30 - Canonical HF Equations
Link NOC:Approximate Methods in Quantum Chemistry Lecture 31 - Hartree-Fock Energy
Link NOC:Approximate Methods in Quantum Chemistry Lecture 32 - Hartree-Fock-Roothan Equations
Link NOC:Approximate Methods in Quantum Chemistry Lecture 33 - The Density Matrix
Link NOC:Approximate Methods in Quantum Chemistry Lecture 34 - Evaluation of Molecular Properties
Link NOC:Approximate Methods in Quantum Chemistry Lecture 35 - Basis Sets - I
Link NOC:Approximate Methods in Quantum Chemistry Lecture 36 - Basis Sets - II
Link NOC:Approximate Methods in Quantum Chemistry Lecture 37 - Electron Correlation and Post HF Methods
Link NOC:Approximate Methods in Quantum Chemistry Lecture 38 - Time-Dependent Perturbation Theory - I
Link NOC:Approximate Methods in Quantum Chemistry Lecture 39 - Time-Dependent Perturbation Theory - II
Link NOC:Approximate Methods in Quantum Chemistry Lecture 40 - Slowly Switched Constant Perturbation
Link NOC:Approximate Methods in Quantum Chemistry Lecture 41 - Oscillating Perturbation
Link NOC:Approximate Methods in Quantum Chemistry Lecture 42 - Einstein’s Coefficients
Link NOC:Biological Inorganic Chemistry Lecture 1 - Metal Ions In Biological Systems
Link NOC:Biological Inorganic Chemistry Lecture 2 - Metallobiosite structures
Link NOC:Biological Inorganic Chemistry Lecture 3 - Biomolecular structure and molecular biology component
Link NOC:Biological Inorganic Chemistry Lecture 4 - Structures of nucleic acids
Link NOC:Biological Inorganic Chemistry Lecture 5 - Coordination Chemistry in action
Link NOC:Biological Inorganic Chemistry Lecture 6 - Coordination of peptide building blocks
Link NOC:Biological Inorganic Chemistry Lecture 7 - Occurrence and availability
Link NOC:Biological Inorganic Chemistry Lecture 8 - Potential ligands of different types
Link NOC:Biological Inorganic Chemistry Lecture 9 - Metal ion insertion
Link NOC:Biological Inorganic Chemistry Lecture 10 - Organic cofactors and siderophores
Link NOC:Biological Inorganic Chemistry Lecture 11 - Introduction
Link NOC:Biological Inorganic Chemistry Lecture 12 - CD and Raman spectroscopy
Link NOC:Biological Inorganic Chemistry Lecture 13 - EPR
Link NOC:Biological Inorganic Chemistry Lecture 14 - NMR and X-ray
Link NOC:Biological Inorganic Chemistry Lecture 15 - Electrochemical methods
Link NOC:Biological Inorganic Chemistry Lecture 16 - Metal ion assimilation
Link NOC:Biological Inorganic Chemistry Lecture 17 - Transport of metal ions in bacteria and plants
Link NOC:Biological Inorganic Chemistry Lecture 18 - Transport of metal ions in fungi and mammals
Link NOC:Biological Inorganic Chemistry Lecture 19 - Homeostasis in bacteria and plants
Link NOC:Biological Inorganic Chemistry Lecture 20 - Homeostasis in fungi and mammals
Link NOC:Biological Inorganic Chemistry Lecture 21 - Transport across membranes
Link NOC:Biological Inorganic Chemistry Lecture 22 - Ion channels and ion pumps
Link NOC:Biological Inorganic Chemistry Lecture 23 - (K+) channels
Link NOC:Biological Inorganic Chemistry Lecture 24 - (Na+) channels
Link NOC:Biological Inorganic Chemistry Lecture 25 - (Na+)-(K+) ATPase
Link NOC:Biological Inorganic Chemistry Lecture 26 - (Mg2+) dependent enzymes and kinases
Link NOC:Biological Inorganic Chemistry Lecture 27 - Phosphatases and enolases
Link NOC:Biological Inorganic Chemistry Lecture 28 - Photoreception and enzymes
Link NOC:Biological Inorganic Chemistry Lecture 29 - (Ca2+) transporting, binding and sensor proteins
Link NOC:Biological Inorganic Chemistry Lecture 30 - Cell signaling by (Ca2+) binding and sensing
Link NOC:Biological Inorganic Chemistry Lecture 31 - Functions of iron ions and iron ion proteins
Link NOC:Biological Inorganic Chemistry Lecture 32 - Heme proteins for (O2) transport and storage
Link NOC:Biological Inorganic Chemistry Lecture 33 - Activators of (O2) and electron transport proteins
Link NOC:Biological Inorganic Chemistry Lecture 34 - Iron-sulfur proteins
Link NOC:Biological Inorganic Chemistry Lecture 35 - Mononuclear and dinuclear non-heme enzymes
Link NOC:Biological Inorganic Chemistry Lecture 36 - Oxygen transport and SOD activity
Link NOC:Biological Inorganic Chemistry Lecture 37 - Type 1 blue copper proteins
Link NOC:Biological Inorganic Chemistry Lecture 38 - Type 2 non-blue copper proteins
Link NOC:Biological Inorganic Chemistry Lecture 39 - Type 3 dinuclear copper proteins
Link NOC:Biological Inorganic Chemistry Lecture 40 - Multicopper and mixed-copper enzymes
Link NOC:Biological Inorganic Chemistry Lecture 41 - Coordination chemistry and function of zinc ions
Link NOC:Biological Inorganic Chemistry Lecture 42 - Carbonic anhydrase and lyases
Link NOC:Biological Inorganic Chemistry Lecture 43 - Carboxypeptidase and metalloproteinases
Link NOC:Biological Inorganic Chemistry Lecture 44 - Alcohol dehydrogenase and Beta-lactamase
Link NOC:Biological Inorganic Chemistry Lecture 45 - Redox catalysis by manganese ions
Link NOC:Biological Inorganic Chemistry Lecture 46 - Redox catalysis by manganese ions
Link NOC:Biological Inorganic Chemistry Lecture 47 - Catalysis by manganese and cobalt ions
Link NOC:Biological Inorganic Chemistry Lecture 48 - Cobalt ion dependent proteins and enzymes
Link NOC:Biological Inorganic Chemistry Lecture 49 - Nickel proteins and enzymes
Link NOC:Biological Inorganic Chemistry Lecture 50 - More nickel ion bearing enzymes
Link NOC:Biological Inorganic Chemistry Lecture 51 - Carbon, hydrogen and oxygen
Link NOC:Biological Inorganic Chemistry Lecture 52 - Nitrogen and Silicon
Link NOC:Biological Inorganic Chemistry Lecture 53 - Phosphorus
Link NOC:Biological Inorganic Chemistry Lecture 54 - Sulfur and Selenium
Link NOC:Biological Inorganic Chemistry Lecture 55 - Chlorine and Iodine
Link NOC:Biological Inorganic Chemistry Lecture 56 - Brain and blood-brain barrier (BBB)
Link NOC:Biological Inorganic Chemistry Lecture 57 - Zinc and copper ions
Link NOC:Biological Inorganic Chemistry Lecture 58 - Iron ions
Link NOC:Biological Inorganic Chemistry Lecture 59 - Metal ion based drugs and metallotherapeutics
Link NOC:Biological Inorganic Chemistry Lecture 60 - Chemotherapy, radiotherapy and contrast agents
Link NOC:Principles and Applications of Enolate Alkylation Lecture 1 - Enolate generation, structure of enolates and related topic - I
Link NOC:Principles and Applications of Enolate Alkylation Lecture 2 - Enolate generation, structure of enolates and related topic - II
Link NOC:Principles and Applications of Enolate Alkylation Lecture 3 - Enolate generation, structure of enolates and related topic - III
Link NOC:Principles and Applications of Enolate Alkylation Lecture 4 - Different mode of asymmetric induction in enolate alkylation
Link NOC:Principles and Applications of Enolate Alkylation Lecture 5 - Revisit again, Different mode of asymmetric induction in enolate alkylation
Link NOC:Principles and Applications of Enolate Alkylation Lecture 6 - Substrate directed stereocontrol in acyclic and cyclic system
Link NOC:Principles and Applications of Enolate Alkylation Lecture 7 - Substrate directed enolate alkylation in bicyclic system
Link NOC:Principles and Applications of Enolate Alkylation Lecture 8 - Seebachâ's SRS principle and related systems - I
Link NOC:Principles and Applications of Enolate Alkylation Lecture 9 - Seebachâ's SRS principle and related systems - II
Link NOC:Principles and Applications of Enolate Alkylation Lecture 10 - Seebachâ's SRS principle and related systems - III
Link NOC:Principles and Applications of Enolate Alkylation Lecture 11 - Evans oxazolidinone and related systems - I
Link NOC:Principles and Applications of Enolate Alkylation Lecture 12 - Evans oxazolidinone and related systems - II
Link NOC:Principles and Applications of Enolate Alkylation Lecture 13 - Evans oxazolidinone and related systems - III
Link NOC:Principles and Applications of Enolate Alkylation Lecture 14 - Evans oxazolidinone and related systems - IV
Link NOC:Principles and Applications of Enolate Alkylation Lecture 15 - Evans oxazolidinone and related systems - V
Link NOC:Principles and Applications of Enolate Alkylation Lecture 16 - Helmchenâ's auxiliary, Oppolzerâ's sultam based auxiliary
Link NOC:Principles and Applications of Enolate Alkylation Lecture 17 - Camphor based N-acyloxazolidinones as chiral auxiliary
Link NOC:Principles and Applications of Enolate Alkylation Lecture 18 - Myerâ's ephedrine, Chiral Weinreb amide equivalents and related systems
Link NOC:Principles and Applications of Enolate Alkylation Lecture 19 - Myerâ's ephedrine and related systems
Link NOC:Principles and Applications of Enolate Alkylation Lecture 20 - Chiral Weinreb amide equivalents and related systems
Link NOC:Principles and Applications of Enolate Alkylation Lecture 21 - Meyerâ's oxazoline based alkylation - I
Link NOC:Principles and Applications of Enolate Alkylation Lecture 22 - Meyerâ's oxazoline based alkylation - II
Link NOC:Principles and Applications of Enolate Alkylation Lecture 23 - Meyerâ's bicyclic lactam based enolate alkylation
Link NOC:Principles and Applications of Enolate Alkylation Lecture 24 - Meyerâ's bicyclic lactam based alkylation
Link NOC:Principles and Applications of Enolate Alkylation Lecture 25 - Meyerâ's bicyclic lactams, Gleasonâ's bicyclic thioglycolate lactam based systems
Link NOC:Principles and Applications of Enolate Alkylation Lecture 26 - Few problem solving from Meyerâ's oxazoline/bicyclic lactam based alkylation
Link NOC:Principles and Applications of Enolate Alkylation Lecture 27 - Schollkopfâ's bis-lactim ether and related systems; Auxiliary induced chiral relay
Link NOC:Principles and Applications of Enolate Alkylation Lecture 28 - Chiral relay systems in amino acid derived enolate alkylation
Link NOC:Principles and Applications of Enolate Alkylation Lecture 29 - Wiliams oxazinone, Yamada's chiral glycine enolate and related system
Link NOC:Principles and Applications of Enolate Alkylation Lecture 30 - Tricycloiminolactone as chiral glycine equivalents
Link NOC:Principles and Applications of Enolate Alkylation Lecture 31 - Najera's auxiliary, Davies diketopoperazine and related system
Link NOC:Principles and Applications of Enolate Alkylation Lecture 32 - Enderâ's RAMP/SAMP,Coltartâ's cyclic carbamate hydrazone,Ellmanâ's sulfinamide and related
Link NOC:Principles and Applications of Enolate Alkylation Lecture 33 - Enderâ's RAMP/SAMP based systems
Link NOC:Principles and Applications of Enolate Alkylation Lecture 34 - Enderâ's RAMP/SAMP based systems
Link NOC:Principles and Applications of Enolate Alkylation Lecture 35 - Enderâ's RAMP/SAMP, Coltartâ's cyclic carbamate hydrazone,Ellmanâ's sulfinamide
Link NOC:Principles and Applications of Enolate Alkylation Lecture 36 - Coltartâ's cyclic carbamate hydrazone and its exploration
Link NOC:Principles and Applications of Enolate Alkylation Lecture 37 - Memory of chirality in enolate alkylation
Link NOC:Principles and Applications of Enolate Alkylation Lecture 38 - Organocatalytic methods for enolate alkylation (SOMO activation)
Link NOC:Principles and Applications of Enolate Alkylation Lecture 39 - Enantioselective alkylation with chiral PTC
Link NOC:Principles and Applications of Enolate Alkylation Lecture 40 - Overall analysis of the entire discussion
Link NOC:Overview and Integration of Cellular Metabolism Lecture 1 - Bioenergetics: Understanding the significance in Biological Systems
Link NOC:Overview and Integration of Cellular Metabolism Lecture 2 - Regulation of Enzyme Activity
Link NOC:Overview and Integration of Cellular Metabolism Lecture 3 - Digestion and Absorption of Carbohydrates
Link NOC:Overview and Integration of Cellular Metabolism Lecture 4 - Glycolysis, alcohol and lactic acid fermentation
Link NOC:Overview and Integration of Cellular Metabolism Lecture 5 - Biochemistry of TCA Cycle (I)
Link NOC:Overview and Integration of Cellular Metabolism Lecture 6 - TCA Cycle (II) - Regulation and special characteristics
Link NOC:Overview and Integration of Cellular Metabolism Lecture 7 - Neoglucogenesis
Link NOC:Overview and Integration of Cellular Metabolism Lecture 8 - Regulation of Glycolysis and Neoglucogenesis - I
Link NOC:Overview and Integration of Cellular Metabolism Lecture 9 - Regulation of Glycolysis and Neoglucogenesis - II Cori Cycle, Rapoport Leubering
Link NOC:Overview and Integration of Cellular Metabolism Lecture 10 - Hexose Monophosphate Shunt : Steps and Phases
Link NOC:Overview and Integration of Cellular Metabolism Lecture 11 - Hexose Monophosphate Shunt : Regulation and Significance
Link NOC:Overview and Integration of Cellular Metabolism Lecture 12 - Glycogen Metabolism - I
Link NOC:Overview and Integration of Cellular Metabolism Lecture 13 - Glycogen Metabolism - II
Link NOC:Overview and Integration of Cellular Metabolism Lecture 14 - Glycogen Metabolism - III
Link NOC:Overview and Integration of Cellular Metabolism Lecture 15 - Glycogen Metabolism - IV
Link NOC:Overview and Integration of Cellular Metabolism Lecture 16 - Galactose Metabolism and Associated Disorders
Link NOC:Overview and Integration of Cellular Metabolism Lecture 17 - Fructose Metabolism and Associated Disorders
Link NOC:Overview and Integration of Cellular Metabolism Lecture 18 - Regulation of Blood Glucose
Link NOC:Overview and Integration of Cellular Metabolism Lecture 19 - Diabetes Mellitus and Metabolic Alterations
Link NOC:Overview and Integration of Cellular Metabolism Lecture 20 - Digestion and absorption of Lipid
Link NOC:Overview and Integration of Cellular Metabolism Lecture 21 - Lipoprotein Metabolism - I
Link NOC:Overview and Integration of Cellular Metabolism Lecture 22 - Lipoprotein Metabolism - II
Link NOC:Overview and Integration of Cellular Metabolism Lecture 23 - Lipoprotein metabolism - III
Link NOC:Overview and Integration of Cellular Metabolism Lecture 24 - Fatty acid catabolism (Oxidation of Fatty acids) - I
Link NOC:Overview and Integration of Cellular Metabolism Lecture 25 - Fatty acid catabolism (Oxidation of Fatty acids) - II
Link NOC:Overview and Integration of Cellular Metabolism Lecture 26 - Fatty acid catabolism (Oxidation of Fatty acids) - III
Link NOC:Overview and Integration of Cellular Metabolism Lecture 27 - Metabolism of Ketone Bodies
Link NOC:Overview and Integration of Cellular Metabolism Lecture 28 - Biosynthesis of Fatty acid and its regulation
Link NOC:Overview and Integration of Cellular Metabolism Lecture 29 - Biosynthesis of triacylglycerol, phosphoglycerides and sphingolipids
Link NOC:Overview and Integration of Cellular Metabolism Lecture 30 - Cholesterol Metabolism
Link NOC:Overview and Integration of Cellular Metabolism Lecture 31 - Digestion and absorption of Protein
Link NOC:Overview and Integration of Cellular Metabolism Lecture 32 - Transformation of Amino acids
Link NOC:Overview and Integration of Cellular Metabolism Lecture 33 - Metabolism of Ammonia and ammonia toxicity
Link NOC:Overview and Integration of Cellular Metabolism Lecture 34 - Urea cycle - Steps, Significance and Energetics
Link NOC:Overview and Integration of Cellular Metabolism Lecture 35 - Urea Cycle - Regulation and Enzyme Deficiency Disorders
Link NOC:Overview and Integration of Cellular Metabolism Lecture 36 - Metabolism of Phenylalanine and Associated Disorders
Link NOC:Overview and Integration of Cellular Metabolism Lecture 37 - Tyrosine Metabolism - I
Link NOC:Overview and Integration of Cellular Metabolism Lecture 38 - Tyrosine Metabolism - II (Catecholamines)
Link NOC:Overview and Integration of Cellular Metabolism Lecture 39 - Tyrosine Metabolism - III
Link NOC:Overview and Integration of Cellular Metabolism Lecture 40 - Tryptophan Metabolism
Link NOC:Overview and Integration of Cellular Metabolism Lecture 41 - Metabolism of Sulphur containing Amino acids (Methionine and Cysteine)
Link NOC:Overview and Integration of Cellular Metabolism Lecture 42 - Metabolism of Glycine and its disorders
Link NOC:Overview and Integration of Cellular Metabolism Lecture 43 - Metabolism of Serine, Threonine and Alanine
Link NOC:Overview and Integration of Cellular Metabolism Lecture 44 - Branched chain amino acid metabolism and their disorders
Link NOC:Overview and Integration of Cellular Metabolism Lecture 45 - Metabolism of Histidine, Proline, Arginine and Lysine
Link NOC:Overview and Integration of Cellular Metabolism Lecture 46 - Heme Metabolism - I (Heme Synthesis and Regulation)
Link NOC:Overview and Integration of Cellular Metabolism Lecture 47 - Heme Metabolism - II (Disorders of Heme Synthesis - Porphyrias)
Link NOC:Overview and Integration of Cellular Metabolism Lecture 48 - Heme Metabolism - III (Heme Degradation, Transport and Bilirubin Metabolism)
Link NOC:Overview and Integration of Cellular Metabolism Lecture 49 - Disorders of Bilirubin Metabolism
Link NOC:Overview and Integration of Cellular Metabolism Lecture 50 - Nucleotide Metabolism - I (Purine Metabolism)
Link NOC:Overview and Integration of Cellular Metabolism Lecture 51 - Nucleotide Metabolism - II (Disorders of Purine Metabolism)
Link NOC:Overview and Integration of Cellular Metabolism Lecture 52 - Nucleotide Metabolism - III (Pyrimidine Metabolism and Disorders)
Link NOC:Overview and Integration of Cellular Metabolism Lecture 53 - Inborn errors of Metabolism
Link NOC:Overview and Integration of Cellular Metabolism Lecture 54 - Integration of Metabolism - I (Cellular and Organ level integration)
Link NOC:Overview and Integration of Cellular Metabolism Lecture 55 - Integration of Metabolism - II (Starve feed cycle)
Link NOC:Overview and Integration of Cellular Metabolism Lecture 56 - Integration of Metabolism - III (Metabolic Control Analysis)
Link NOC:Overview and Integration of Cellular Metabolism Lecture 57 - Obesity, Metabolic Syndrome and Role of Adipokines
Link NOC:Overview and Integration of Cellular Metabolism Lecture 58 - Fatty Liver and alcohol metabolism
Link NOC:Overview and Integration of Cellular Metabolism Lecture 59 - Energy metabolism and Nutritional disorders, Protein Energy Malnutrition and Dietary
Link NOC:Overview and Integration of Cellular Metabolism Lecture 60 - Metabolism in Cancer Cells
Link NOC:Elementary Thermodynamics for All Lecture 1 - Introduction
Link NOC:Elementary Thermodynamics for All Lecture 2 - System, Equilibrium States
Link NOC:Elementary Thermodynamics for All Lecture 3 - Mathematical foundation - Exact differentials
Link NOC:Elementary Thermodynamics for All Lecture 4 - Mathematical foundation - Inexact differentials
Link NOC:Elementary Thermodynamics for All Lecture 5 - First law - Introduction to Internal energy
Link NOC:Elementary Thermodynamics for All Lecture 6 - First law - Heat and work
Link NOC:Elementary Thermodynamics for All Lecture 7 - First law - Pressure-volume work
Link NOC:Elementary Thermodynamics for All Lecture 8 - First law - Internal energy revisited
Link NOC:Elementary Thermodynamics for All Lecture 9 - First Law - Enthalpy
Link NOC:Elementary Thermodynamics for All Lecture 10 - First law - Estimation of change in internal energy and enthalpy
Link NOC:Elementary Thermodynamics for All Lecture 11 - Second law - Introduction
Link NOC:Elementary Thermodynamics for All Lecture 12 - Second law - Carnot engine and entropy
Link NOC:Elementary Thermodynamics for All Lecture 13 - Entropy and Third law
Link NOC:Elementary Thermodynamics for All Lecture 14 - Entropy and Spontaneity in isolated systems
Link NOC:Elementary Thermodynamics for All Lecture 15 - Spontaneity and equilibrium - Thermodynamic potentials
Link NOC:Elementary Thermodynamics for All Lecture 16 - Spontaneity and equilibrium - Non-isolated systems
Link NOC:Elementary Thermodynamics for All Lecture 17 - Thermodynamic potentials and Maxwell's relations
Link NOC:Elementary Thermodynamics for All Lecture 18 - Application of Maxwell's relations
Link NOC:Elementary Thermodynamics for All Lecture 19 - Thermodynamic response functions
Link NOC:Elementary Thermodynamics for All Lecture 20 - Using Maxwell's relations to solve numerical problems
Link NOC:Elementary Thermodynamics for All Lecture 21 - Fundamental Equation of Chemical Thermodynamics
Link NOC:Elementary Thermodynamics for All Lecture 22 - Open systems and chemical potential
Link NOC:Elementary Thermodynamics for All Lecture 23 - Chemical potential in one and many component ideal gas
Link NOC:Elementary Thermodynamics for All Lecture 24 - Gibbs-Duhem relation and thermodynamics of ideal gas mixture
Link NOC:Elementary Thermodynamics for All Lecture 25 - Numerical applications of Gibbs-Duhem relation
Link NOC:Elementary Thermodynamics for All Lecture 26 - Phase equilibrium - Part 1
Link NOC:Elementary Thermodynamics for All Lecture 27 - Phase equilibrium - Part 2
Link NOC:Elementary Thermodynamics for All Lecture 28 - Phase equilibrium - Part 3
Link NOC:Elementary Thermodynamics for All Lecture 29 - Phase equilibrium - Part 4
Link NOC:Elementary Thermodynamics for All Lecture 30 - Numerical problems in phase equilibrium
Link NOC:Elementary Thermodynamics for All Lecture 31 - Simple non-reactive mixtures - Part 1
Link NOC:Elementary Thermodynamics for All Lecture 32 - Simple non-reactive mixtures - Part 2
Link NOC:Elementary Thermodynamics for All Lecture 33 - Numerical problems in simple mixtures
Link NOC:Elementary Thermodynamics for All Lecture 34 - Numerical problems on phase equilibrium in simple mixtures
Link NOC:Elementary Thermodynamics for All Lecture 35 - Chemical potential of real systems - Activity and concentration
Link NOC:Elementary Thermodynamics for All Lecture 36 - Numerical problems on chemical potential in real systems
Link NOC:Elementary Thermodynamics for All Lecture 37 - Chemical Equilibrium - Part I
Link NOC:Elementary Thermodynamics for All Lecture 38 - Chemical Equilibrium - Part II
Link NOC:Elementary Thermodynamics for All Lecture 39 - Chemical Equilibrium - Part III
Link NOC:Elementary Thermodynamics for All Lecture 40 - Chemical Equilibrium - Part IV
Link NOC:Elementary Thermodynamics for All Lecture 41 - Numerical problems on chemical equilibrium
Link NOC:Elementary Thermodynamics for All Lecture 42 - Numerical problems on chemical equilibrium (Continued...)
Link NOC:Elementary Thermodynamics for All Lecture 43 - Electrochemical equilibrium - Part I
Link NOC:Elementary Thermodynamics for All Lecture 44 - Electrochemical equilibrium - Part II
Link NOC:Elementary Thermodynamics for All Lecture 45 - Electrochemical equilibrium - Part III
Link NOC:Elementary Thermodynamics for All Lecture 46 - Electrochemical equilibrium - Part IV
Link NOC:Elementary Thermodynamics for All Lecture 47 - Electrochemical equilibrium - Part V
Link NOC:Elementary Thermodynamics for All Lecture 48 - Electrochemical equilibrium - Part VI
Link NOC:Elementary Thermodynamics for All Lecture 49 - Numerical problems on electrochemistry
Link NOC:Elementary Thermodynamics for All Lecture 50 - Numerical problems on electrochemistry (Continued...)
Link NOC:Elementary Thermodynamics for All Lecture 51 - Numerical problems on electrochemistry (Continued...)
Link NOC:Elementary Thermodynamics for All Lecture 52 - Numerical problems on electrochemistry (Continued...)
Link NOC:Elementary Thermodynamics for All Lecture 53 - Numerical problems on electrochemistry (Continued...)
Link NOC:Elementary Thermodynamics for All Lecture 54 - Thermodynamic stability
Link NOC:Elementary Thermodynamics for All Lecture 55 - Thermodynamics in action - Part I
Link NOC:Elementary Thermodynamics for All Lecture 56 - Thermodynamics in action - Part II
Link NOC:Elementary Thermodynamics for All Lecture 57 - Thermodynamics in action - Part III
Link NOC:Elementary Thermodynamics for All Lecture 58 - Thermodynamics in action - Part IV
Link NOC:Elementary Thermodynamics for All Lecture 59 - Demonstration
Link NOC:Elementary Thermodynamics for All Lecture 60 - Concluding Lecture
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 1 - Carbocation
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 2 - Carbocation (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 3 - Carbocation (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 4 - Carbocation (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 5 - Carbocation (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 6 - Carbanion
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 7 - Carbanion (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 8 - Carbanion (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 9 - Carbanion (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 10 - Carbanion (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 11 - Carbene
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 12 - Carbene (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 13 - Carbene (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 14 - Carbene (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 15 - Nitrene
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 16 - Nitrene(Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 17 - Radical
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 18 - Radical (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 19 - Free Radical
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 20 - Radical
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 21 - Radical
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 22 - Free Radical (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 23 - Radical
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 24 - Free Radical Reactions
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 25 - Radical (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 26 - Radical (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 27 - Radical (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 28 - Benzyne
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 29 - Benzyne (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 30 - Benzyne (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 31 - Benzyne question answer discussion
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 32 - Organolithium
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 33 - Organolithium (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 34 - Organolithium (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 35 - Organolithium (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 36 - Organolithium (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 37 - Grignard
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 38 - Grignard (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 39 - Organocopper
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 40 - Organozinc
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 41 - Organoboron Chemistry
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 42 - Organoboron Chemistry (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 43 - Organoboron Chemistry (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 44 - Organoboron Chemistry (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 45 - Organoboron
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 46 - Organoboron Chemistry
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 47 - Organosilicon Chemistry
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 48 - Organosilicon Chemistry (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 49 - Organosilicon Chemistry (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 50 - Organosulfur Chemistry
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 51 - Organosulfur
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 52 - Organosulfur (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 53 - Organosulfur (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 54 - Organophosphorus Chemistry
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 55 - Organophosphorus Chemistry (Continued...)
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 56 - Tutorial 1
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 57 - Tutorial 2
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 58 - Tutorial 3
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 59 - Tutorial 4
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 60 - Tutorial 5
Link NOC:Molecular Rearrangements and Reactive Intermediates in Organic Synthesis Lecture 61 - Tutorial 6
Link Principles and Application of Electron Paramagnetic Resonance Lecture 1 - Remembering the Masters: From Zeeman to Zavoisky
Link Principles and Application of Electron Paramagnetic Resonance Lecture 2 - Introduction to EPR spectroscopy
Link Principles and Application of Electron Paramagnetic Resonance Lecture 3 - Electron-Nuclear Hyperfine Interaction - I
Link Principles and Application of Electron Paramagnetic Resonance Lecture 4 - Electron-Nuclear Hyperfine Interaction - II
Link Principles and Application of Electron Paramagnetic Resonance Lecture 5 - Magnetic Moment in Magnetic Field - I
Link Principles and Application of Electron Paramagnetic Resonance Lecture 6 - Magnetic Moment in Magnetic Field - II
Link Principles and Application of Electron Paramagnetic Resonance Lecture 7 - EPR Instrumentations - I
Link Principles and Application of Electron Paramagnetic Resonance Lecture 8 - EPR Instrumentations - II
Link Principles and Application of Electron Paramagnetic Resonance Lecture 9 - EPR Instrumentations - III
Link Principles and Application of Electron Paramagnetic Resonance Lecture 10 - EPR Instrumentations - IV
Link Principles and Application of Electron Paramagnetic Resonance Lecture 11 - Quantum Mechanical Description of EPR - I
Link Principles and Application of Electron Paramagnetic Resonance Lecture 12 - Quantum Mechanical Description of EPR - II
Link Principles and Application of Electron Paramagnetic Resonance Lecture 13 - Introduction to Spin Relaxation
Link Principles and Application of Electron Paramagnetic Resonance Lecture 14 - Theory of First-order EPR Spectra - I
Link Principles and Application of Electron Paramagnetic Resonance Lecture 15 - Theory of First-order EPR Spectra - II
Link Principles and Application of Electron Paramagnetic Resonance Lecture 16 - How to Analyse First-order EPR Spectra
Link Principles and Application of Electron Paramagnetic Resonance Lecture 17 - How to Record EPR Spectra
Link Principles and Application of Electron Paramagnetic Resonance Lecture 18 - Second-order Effects on EPR Spectra
Link Principles and Application of Electron Paramagnetic Resonance Lecture 19 - Photochemistry and EPR Spectroscopy
Link Principles and Application of Electron Paramagnetic Resonance Lecture 20 - Electron Spin Polarisation - I
Link Principles and Application of Electron Paramagnetic Resonance Lecture 21 - Electron Spin Polarisation - II
Link Principles and Application of Electron Paramagnetic Resonance Lecture 22 - Anisotropic Interactions in EPR Spectroscopy
Link Principles and Application of Electron Paramagnetic Resonance Lecture 23 - Theoretical Basis of isotropic Hyperfine Coupling
Link Principles and Application of Electron Paramagnetic Resonance Lecture 24 - Spin Relaxation and Bloch Equations - I
Link Principles and Application of Electron Paramagnetic Resonance Lecture 25 - Spin Relaxation and Bloch Equations - II
Link NOC:Chemistry-I Lecture 1
Link NOC:Chemistry-I Lecture 2
Link NOC:Chemistry-I Lecture 3 - Part I
Link NOC:Chemistry-I Lecture 3 - Part II
Link NOC:Chemistry-I Lecture 4 - Part I
Link NOC:Chemistry-I Lecture 4 - Part II
Link NOC:Chemistry-I Lecture 4 - Part III
Link NOC:Chemistry-I Lecture 5 - Part I
Link NOC:Chemistry-I Lecture 5 - Part II
Link NOC:Chemistry-I Lecture 5 - Part III
Link NOC:Chemistry-I Lecture 5 - Part IV
Link NOC:Chemistry-I Lecture 5 - Part V
Link NOC:Chemistry-I Lecture 6 - Part I
Link NOC:Chemistry-I Lecture 6 - Part II
Link NOC:Chemistry-I Lecture 6 - Part III
Link NOC:Chemistry-I Lecture 6 - Part IV
Link NOC:Chemistry-I Lecture 7 - Part I
Link NOC:Chemistry-I Lecture 7 - Part II
Link NOC:Chemistry-I Lecture 8 - Part I
Link NOC:Chemistry-I Lecture 8 - Part II
Link NOC:Chemistry-I Lecture 8 - Part III
Link NOC:Chemistry-I Lecture 9 - Part I
Link NOC:Chemistry-I Lecture 9 - Part II
Link NOC:Chemistry-I Lecture 9 - Part III
Link NOC:Chemistry-I Lecture 10
Link NOC:Chemistry-II Lecture 1 - Electromagnetic radiation
Link NOC:Chemistry-II Lecture 2 - Interaction of radiation with matter
Link NOC:Chemistry-II Lecture 3 - Introduction to chemical applications
Link NOC:Chemistry-II Lecture 4 - Analysis of spectra
Link NOC:Chemistry-II Lecture 5 - Radiation densities and Einstein's semi classical model
Link NOC:Chemistry-II Lecture 6 - Introduction to quantum mechanics - I
Link NOC:Chemistry-II Lecture 7 - Introduction to quantum mechanics - II
Link NOC:Chemistry-II Lecture 8 - Born-Oppenheimer approximation
Link NOC:Chemistry-II Lecture 9 - Beer-Lambert law
Link NOC:Chemistry-II Lecture 10 - Diatomic Vibration Spectra Hermonic Model
Link NOC:Chemistry-II Lecture 11 - Diatomic Vibration Morse Oscillator Model
Link NOC:Chemistry-II Lecture 12 - Normal Vibrational modes Triatomic molecules
Link NOC:Chemistry-II Lecture 13 - Normal Vibrational modes Polyatomic molecules
Link NOC:Chemistry-II Lecture 14 - Vibrational Polyatomic Infrared Spectroscopy Local Modes and Group Frequencies
Link NOC:Chemistry-II Lecture 15 - Microwave spectra of di-atomic molecules
Link NOC:Chemistry-II Lecture 16 - Diatomic Molecules Microwave Energies and Transitions
Link NOC:Chemistry-II Lecture 17 - Methodology of solving problems
Link NOC:Chemistry-II Lecture 18 - Rotational and Vibrational Line Intensities
Link NOC:Chemistry-II Lecture 19 - Microwave Spectra of Polyatomic molecules (Symmetric tops)
Link NOC:Chemistry-II Lecture 20 - Video Tutorial 2 : Part - I
Link NOC:Chemistry-II Lecture 21 - Video Tutorial 2 : Part - II
Link NOC:Chemistry-II Lecture 22 - Introduction to Tensors
Link NOC:Chemistry-II Lecture 23 - Polarizability Tensor
Link NOC:Chemistry-II Lecture 24 - Introduction to Rotational Raman Spectra.
Link NOC:Chemistry-II Lecture 25 - Review of basic concepts in Molecular Spectroscopy
Link NOC:Chemistry-II Lecture 26 - Review of Microwave Spectroscopy
Link NOC:Chemistry-II Lecture 27 - Review of Elementary Vibrational Spectroscopy
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 1
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 2
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 3
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 4
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 5
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 6
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 7
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 8
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 9
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 10
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 11
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 12
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 13
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 14
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 15
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 16
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 17
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 18
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 19
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 20
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 21
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 22
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 23
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 24
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 25
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 26
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 27
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 28
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 29
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 30
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 31
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 32
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 33
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 34
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 35
Link NOC:Application of Spectroscopic Methods in Molecular Structure Determination Module 36
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 1 - Activation of chemical reactions. Thermal and photochemical methods
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 2 - MOs of polyene and their symmetry properties and methods of analyzing pericyclic reactions
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 3 - Introduction to electrocyclic reactions and Woodward Hoffmann rules
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 4 - Electrocyclic reactions – examples of 3, 4 and 5 membered ring systems (2e and 4e systems)
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 5 - Electrocyclic reactions – examples of 6 and larger ring systems (6e and more)
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 6 - Tutorial session 1
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 7 - Cycloaddtion reactions - Introduction and Woodward Hoffmann rules - [2+2] cycloadditions
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 8 - Cycloaddition reactions – ketene cycloadditions
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 9 - Cycloaddition reactions – Diels-Alder reaction - Woodward Hoffmann rule - Regiochemistry and Stereochemistry aspects
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 10 - Diels Alder reaction - synthetic applications
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 11 - Diels Alder reaction continued - Hetero diene and dienophile - Lewis acid mediated - asymmetric
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 12 - 1,3-Dipolar cycloaddition reactions
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 13 - 1,3-Dipolar cycloaddition reactions (Continued...)
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 14 - [4pi+4pi], [4pi+6pi] and higher order cycloaddition reactions
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 15 - Tutorial session 2 on cycloaddition reactions
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 16 - Pericyclic reactions – Sigmatropic rearrangements – Introduction and [1,3] migrations
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 17 - Pericyclic reactions – Sigmatropic rearrangements (Continued...) [1,5] H and C migrations and Cope rearrangement
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 18 - Pericyclic reactions – Sigmatropic rearrangements (Continued...) oxy Cope and Claisen Rearrangement
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 19 - Pericyclic reactions – Sigmatropic rearrangements (Continued...)
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 20 - Pericyclic reactions – Sigmatropic rearrangements (Continued...) [2,3] sigmatropic shifts and higher order rearrangements Completed
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 21 - Pericyclic reactions – Sigmatropic rearrangements (Continued...) Wittig rearrangement and higher order Sigmatropic shifts
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 22 - Pericyclic reactions – Chelotropic reactions - introduction, SO2 extrusion reactions
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 23 - Pericyclic reactions – Tutorial session 3 - Problems on sigmatropic reactions
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 24 - Chelotropic reactions 2
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 25 - The Ene Reaction
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 26 - Tutorial session - 4
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 27 - Introduction to organic photochemistry
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 28 - Photochemistry of alkenes cis-trans isomerization
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 29 - Photochemistry of alkenes (Continued...)
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 30 - Photochemistry of carbonyl compounds, Norrish type1 and 2 reactions
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 31 - Photochemistry of carbonyl compounds, enone and dienone photochemistry
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 32 - Photochemistry of Nitrogen compounds
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 33 - Photochemistry of aromatic compounds
Link NOC:Pericyclic Reactions and Organic Photochemistry Lecture 34 - Photoinduced electron transfer reactions
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 1 - Lecture 1 - Historical context and experiments: Introducing the Schrödinger equation
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 2 - Lecture 2 - Bohr's atom, De Broglie Matter Waves and Schrodinger equation
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 3 - Lecture 3 - Electromagnetic Radiation
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 4 - Lecture 4 - Interaction of Radiation with Matter
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 5 - Lecture 5 - Molecular Spectroscopy
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 6 - Lecture 6 - Elementary Mathematical Functions 1
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 7 - Lecture 7 - Review of Properties of Elementary Functions II
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 8 - Lecture 8 - Time Dependent Schrödinger Equation & Time Independent Schrödinger Equation
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 9 - Lecture 9 - Schrödinger Equation Particle in a One-dimensional Box : Part I
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 10 - Lecture 10 - Schrödinger Equation Particle in a One-dimensional Box : Part II
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 11 - Lecture 11 - Schrödinger Equation Particle in Two-dimensional Box : Part I
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 12 - Lecture 12 - Particle in Two-dimensional Box : Part II Uncertainty Principle
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 13 - Lecture 13 - Particle in Two-dimensional Box : Part III Expectation Values
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 14 - Lecture 14 - The Quantum Mechanics of Hydrogen Atom - Part I
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 15 - Lecture 15 - The Quantum Mechanics of Hydrogen Atom - Part II
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 16 - Lecture 16 - The Quantum Mechanics of Hydrogen Atom - Part III
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 17 - Lecture 17 - The Quantum Mechanics of Hydrogen Atom - Part IV
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 18 - Lecture 18 - The Quantum Mechanics of Hydrogen Atom - Part V
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 19 - Lecture 19A - Assignment 1 Solution/Hints
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 20 - Lecture 19B - Assignment 1 Solution/Hints
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 21 - Lecture 19C - Assignment 1 Solution/Hints
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 22 - Lecture 19D - Assignment 1 Solution/Hints
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 23 - Lecture 19E - Assignment 1 Solution/Hints
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 24 - Lecture 20 - Harmonic Oscillator Model - Part I
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 25 - Lecture 21 - Harmonic Oscillator Model - Part II
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 26 - Lecture 22 - Harmonic Oscillator Model - Part III
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 27 - Lecture 23 - Harmonic Oscillator Model - Part IV
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 28 - Lecture 24 - Particle on a Ring - Part I
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 29 - Lecture 25 - Particle on a Ring - Part II
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 30 - Lecture 26 - Heisenberg’s Uncertainty Relation
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 31 - Lecture 27A - Operators, Commutators, Eigenvalues and Eigenvectors
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 32 - Lecture 27B - Operators, Commutators, Eigenvalues and Eigenvectors
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 33 - Lecture 28 - Introduction to Chemical Applications
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 34 - Lecture 29 - Radiation Densities and Einstein’s Semiclassical model
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 35 - Lecture 30 - Born Oppenheimer Approximation
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 36 - Lecture 31 - Beer Lambert Law
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 37 - Lecture 32 - Diatomic Vibrational Spectra Harmonic Model
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 38 - Lecture 33 - Diatomic Vibration Morse Oscillator Model
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 39 - Lecture 34 - Molecular Vibrations in Polyatomic Molecules - Qualitative Account
Link NOC:Chemistry I:Introduction To Quantum Chemistry And Molecular Spectroscopy Lecture 40 - Lecture 35 - Polyatomic Vibrations - Illustrative examples of normal vibrations
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 1 - Introduction to Chemical Thermodynamics and Kinetics
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 2 - Properties of gases - Part 1
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 3 - Properties of gases - Part 2
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 4 - Introduction - Part 1
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 5 - Introduction - Part 2
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 6 - First law - Part 1
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 7 - First law - Part 2
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 8 - First law - Part 3
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 9 - First law - Part 4
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 10 - First law - Part 5
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 11 - Second law - Part 1
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 12 - Second law - Part 2
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 13 - Spontaneity and equilibrium - Part 1
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 14 - Spontaneity and equilibrium - Part 2
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 15 - Spontaneity and equilibrium - Part 3
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 16 - Phase equilibrium - Part 1
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 17 - Phase equilibrium - Part 2
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 18 - Phase equilibrium - Part 3
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 19 - Phase equilibrium - Part 4
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 20 - Phase equilibrium - Part 5
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 21 - Phase equilibrium - Part 6
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 22 - Phase equilibrium - Part 7
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 23 - Mixtures - Part 1
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 24 - Mixtures - Part 2
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 25 - Mixtures - Part 3
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 26 - Mixtures - Part 4
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 27 - Mixtures - Part 5
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 28 - Chemical Equilibrium - Part 1
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 29 - Chemical Equilibrium - Part 2
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 30 - Chemical Equilibrium - Part 3
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 31 - Chemical Equilibrium - Part 4
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 32 - Chemical Equilibrium - Part 5
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 33 - Chemical equilibrium - Part 2B
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 34 - Chemical equilibrium - Part 2C
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 35 - Electrochemistry - Part 1
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 36 - Electrochemistry - Part 2
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 37 - Electrochemistry - Part 3
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 38 - Surfaces and interfaces
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 39 - Chemical Kinetics: Rate laws - Part 1
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 40 - Chemical Kinetics: Rate laws - Part 2
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 41 - Chemical Kinetics: Rate laws - Part 3
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 42 - Chemical Kinetics: Rate laws - Part 4
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 43 - Chemical Kinetics: Mechanisms - Part 1
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 44 - Chemical Kinetics: Mechanisms - Part 2
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 45 - Chemical Kinetics: Mechanisms - Part 3
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 46 - Chemical Kinetics: Mechanisms - Part 4
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 47 - Chemical Kinetics: Mechanisms - Part 5
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 48 - Chemical Kinetics: Mechanisms - Part 6
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 49 - Reaction dynamics - Part 1
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 50 - Reaction dynamics - Part 2
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 51 - Reaction dynamics - Part 3
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 52 - Reaction dynamics - Part 4
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 53 - Reaction dynamics - Part 5
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 54 - Reaction dynamics - Part 6
Link NOC:Introduction to Chemical Thermodynamics and Kinetics Lecture 55 - Reaction dynamics - Part 7
Link NOC:Chemical Crystallography Lecture 1 - Introduction to X-Ray Crystallography
Link NOC:Chemical Crystallography Lecture 2 - Sources of X-Rays, Crystal Systems and Bravais lattices
Link NOC:Chemical Crystallography Lecture 3 - Crystallographic Symmetries
Link NOC:Chemical Crystallography Lecture 4 - Equivalent Points and 1D Lattices
Link NOC:Chemical Crystallography Lecture 5 - 5 Fold Symmetry and 2D Lattices
Link NOC:Chemical Crystallography Lecture 6 - 2D Space Lattices
Link NOC:Chemical Crystallography Lecture 7 - Crystallographic Point Groups
Link NOC:Chemical Crystallography Lecture 8 - Stereographic Projections of Point Groups
Link NOC:Chemical Crystallography Lecture 9 - Understanding of Crystallographic Space Groups
Link NOC:Chemical Crystallography Lecture 10 - 2D Projection of Space Groups
Link NOC:Chemical Crystallography Lecture 11 - Tutorial - 01
Link NOC:Chemical Crystallography Lecture 12 - 3D Space Groups and Equivalent Points
Link NOC:Chemical Crystallography Lecture 13 - Obtaining Equivalent Points by Shifting of Origin
Link NOC:Chemical Crystallography Lecture 14 - Representation of Orthorhombic and Tetragonal Space Groups
Link NOC:Chemical Crystallography Lecture 15 - Miller Indices for Crystallographic Directions and Planes
Link NOC:Chemical Crystallography Lecture 16 - Miller Indices and Planar Densities
Link NOC:Chemical Crystallography Lecture 17 - Tutorial - 02
Link NOC:Chemical Crystallography Lecture 18 - Cubic Structues and atomic packing factors
Link NOC:Chemical Crystallography Lecture 19 - Ceramic Structures
Link NOC:Chemical Crystallography Lecture 20 - Theory of X-Ray Diffraction
Link NOC:Chemical Crystallography Lecture 21 - Tutorial - 03
Link NOC:Chemical Crystallography Lecture 22 - Origin of Reciprocal Lattice
Link NOC:Chemical Crystallography Lecture 23 - Bragg's Law in Reciprocal Lattice and Origin of Systematic Absences
Link NOC:Chemical Crystallography Lecture 24 - Systematic Absences and Crystallisation Methods
Link NOC:Chemical Crystallography Lecture 25 - Special Method of Crystallisation
Link NOC:Chemical Crystallography Lecture 26 - Tutorial
Link NOC:Chemical Crystallography Lecture 27 - Single Crystal X-Ray Diffraction Data Collection
Link NOC:Chemical Crystallography Lecture 28 - Diffractometers
Link NOC:Chemical Crystallography Lecture 29 - Diffractometers and Detectors
Link NOC:Chemical Crystallography Lecture 30 - Laue's and Bragg's Analysis
Link NOC:Chemical Crystallography Lecture 31 - Experimental Methods and Theoretical Understanding of X-Ray Diffraction
Link NOC:Chemical Crystallography Lecture 32 - Derivation of Friedel's Law from Structure Factor by Vector Space Diagram
Link NOC:Chemical Crystallography Lecture 33 - Structure Fcator and Electron Density
Link NOC:Chemical Crystallography Lecture 34 - Systematic Absence Conditions from Special Structure Factor Expression
Link NOC:Chemical Crystallography Lecture 35 - Structure Refinement
Link NOC:Chemical Crystallography Lecture 36 - Single Crystal X-Ray Diffractometer
Link NOC:Chemical Crystallography Lecture 37 - Understanding the X-Ray Data
Link NOC:Chemical Crystallography Lecture 38 - Data Handling (Solution and Refinement) using Various Crystallographic Packages
Link NOC:Chemical Crystallography Lecture 39 - Structure Solution using Apex II (Bruker Diffractometer)
Link NOC:Chemical Crystallography Lecture 40 - Structure Solution using Olex 2 (Rigaku Diffractometer)
Link NOC:Chemical Crystallography Lecture 41 - Disorders in Crystal Structures
Link NOC:Chemical Crystallography Lecture 42 - Disorder Treatment using Olex 2
Link NOC:Chemical Crystallography Lecture 43 - Cambridge Structure Database and its Application
Link NOC:Chemical Crystallography Lecture 44 - Data Reduction - Absorption Correction
Link NOC:Chemical Crystallography Lecture 45 - Data Reduction - Lorentz and Polarization Correction
Link NOC:Chemical Crystallography Lecture 46 - Data Reduction - Scale and Temperature Factor
Link NOC:Chemical Crystallography Lecture 47 - Identification from Intensity Statistics the Correct Crystal System and Presence of Inversion Center
Link NOC:Chemical Crystallography Lecture 48 - Identification from Intensity Statistics the presence of 2 fold axis in Lattice
Link NOC:Chemical Crystallography Lecture 49 - Phase Problem
Link NOC:Chemical Crystallography Lecture 50 - Direct Methods - Part 1
Link NOC:Chemical Crystallography Lecture 51 - Direct Methods - Part 2
Link NOC:Chemical Crystallography Lecture 52 - Sigma 1 and Triplet Relationship
Link NOC:Chemical Crystallography Lecture 53 - Patterson Method
Link NOC:Chemical Crystallography Lecture 54 - Powder X-Ray Diffractometer - Theory
Link NOC:Chemical Crystallography Lecture 55 - Powder X-Ray Diffractometer - Lab
Link NOC:Chemical Crystallography Lecture 56 - Polymorphs
Link NOC:Chemical Crystallography Lecture 57 - Polymorphs
Link NOC:Chemical Crystallography Lecture 58 - Review of Reciprocal Lattice
Link NOC:Chemical Crystallography Lecture 59 - Review of Reciprocal Lattice
Link NOC:Chemical Crystallography Lecture 60 - Review of Reciprocal Lattice and Bragg's Law in Reciprocal Lattice
Link NOC:Chemical Crystallography Lecture 61 - Ewald's Sphere and Limiting Sphere
Link NOC:Chemical Crystallography Lecture 62 - Origin of/Introduction to Systematic absences
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 1 - Review of Classical Thermodynamics - 1
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 2 - Review of Classical Thermodynamics - 2
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 3 - Review of Classical Thermodynamics - 3
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 4 - Review of Classical Thermodynamics - 4
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 5 - Review of Classical Thermodynamics - 5
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 6 - Molecular Interactions - 1
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 7 - Molecular Interactions - 2
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 8 - Molecular Interactions - 3
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 9 - Molecular Interactions - 4
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 10 - Molecular Interactions - 5
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 11 - Transport Phenomena - 1
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 12 - Transport Phenomena - 2
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 13 - Transport Phenomena - 3
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 14 - Review of Chemical Kinetics - 1
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 15 - Review of Chemical Kinetics - 2
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 16 - Review of Chemical Kinetics - 3
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 17 - Review of Chemical Kinetics - 4
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 18 - Review of Chemical Kinetics - 5
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 19 - Advanced Topic in Chemical Kinetics - 1
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 20 - Advanced Topic in Chemical Kinetics - 2
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 21 - Advanced Topic in Chemical Kinetics - 3
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 22 - Introduction to statistical thermodynamics - 1
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 23 - Introduction to statistical thermodynamics - 2
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 24 - Introduction to statistical thermodynamics - 3
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 25 - Introduction to bimolecular reaction dynamics - 1
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 26 - Introduction to bimolecular reaction dynamics - 2
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 27 - Introduction to bimolecular reaction dynamics - 3
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 28 - Introduction to bimolecular reaction dynamics - 4
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 29 - Unimolecular reaction - 1
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 30 - Unimolecular reaction - 2
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 31 - Introduction to solution phase reactions dynamics - 1
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 32 - Introduction to solution phase reactions dynamics - 2
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 33 - Introduction to solution phase reactions dynamics - 3
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 34 - Introduction to solution phase reactions dynamics - 4
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 35 - Introduction to solution phase reactions dynamics - 5
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 36 - Non-ideal solutions, Activity of ions (Debye-Huckel theory) - 1
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 37 - Non-ideal solutions, Activity of ions (Debye-Huckel theory) - 2
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 38 - Electrochemistry: Insights into electrode processes, Ionic conductivity - 1
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 39 - Electrochemistry: Insights into electrode processes, Ionic conductivity - 2
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 40 - Reaction Dynamics: Femtosecond Pump Probe Spectroscopy
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 41 - Chemical Kinetics: Hydrolysis of an ester
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 42 - Transport Phenomena: Coefficient of viscosity
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 43 - Equilibrium constant using partition method
Link NOC:Advanced Chemical Thermodynamics and Kinetics Lecture 44 - Photochemistry: Degradation of a dye
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 1 - Welcome
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 2 - Elementary Mathematical Functions Used in Our Course
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 3 - Schrodinger Equation: Particle in a One Dimensional Box
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 4 - Particle in a One dimensional Box: Probabilities and Expectation Values
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 5 - Elementary Mathematics: Introduction to Matrix Algebra - Part 1
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 6 - Elementary Mathematics: Introduction to Matrix Algebra - Part 2
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 7 - Elementary Mathematics: Matrix Eigenvalues and Eigenfunctions - Part I
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 8 - Elementary Mathematics: Matrix Eigenvalues and Eigenfunctions - Part II
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 9 - Particle in a Two Dimensional Box (Infinite Barrier)
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 10 - Heisenberg’s Uncertainty Principle
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 11 - Expectation Values and Postulates in Quantum Mechanics
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 12 - Problems and Solutions for Particle in One and Two Dimensional Boxes
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 13 - Linear Vector Spaces: Matrix Representations
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 14 - Linear Vector Spaces and Operators: Dirac’s Bracket Notation
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 15 - Simple Harmonic Oscillator: Classical Hamiltonian
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 16 - Simple Harmonic Oscillator: Quantum Mechanical Solutions
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 17 - Simple Harmonic Oscillator: Wave Functions, Probabilities and Average Values
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 18 - Simple Harmonic Oscillator: Average Values for Position and Momentum
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 19 - Particle on a Ring: The Quantum Model
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 20 - Particle on a Ring: Expectation Values for Angular Momentum
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 21 - Coordinate Transformation
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 22 - Problems and Solutions for Harmonic Oscillator
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 23 - Hydrogen Atom: The Hamiltonian in Spherical Polar Coordinates
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 24 - Hydrogen Atom: Separation of the Schrödinger Equation
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 25 - Hydrogen Atom: Radial and Angular Solutions and Animations - Part I
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 26 - Hydrogen Atom: Radial and Angular Solutions and Animations - Part II
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 27 - Hydrogen Atom: Radial Solutions and Probabilities
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 28 - Power Series Method for Differential Equation - I
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 29 - Hermite’s Differential Equation
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 30 - Legendre and Associated Legendre Equation
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 31 - Born-Oppenheimer Approximation
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 32 - Introduction to Angular Momentum
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 33 - Spin ½ Angular Momentum
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 34 - Spin Angular Momentum and Coupling of Two Spin-1/2 Angular Momenta
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 35 - Coupling of Two Angular Momenta
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 36 - Video Tutorial for Hermite polynomials and hydrogen atom - Part 1
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 37 - Video Tutorials - Part 2
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 38 - Variational Principle in Quantum Chemistry: Linear superposition Principle
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 39 - Introduction to Variational Principle in Quantum Chemistry
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 40 - Variational Method: Method of Lagrange Multipliers
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 41 - Hydrogen Molecule Ion: The Molecular Orbital Method
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 42 - Hydrogen Molecule Ion: Calculations and Results
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 43 - Hydrogen Molecule: The Valence Bond Method
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 44 - Hydrogen Molecule: Calculations and Molecular Orbital Method
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 45 - Video Tutorials on Angular Momentum (Orbital and Spin) and Variational Method - Part 1
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 46 - Video Tutorials on Angular Momentum (Orbital and Spin) and Variational Method - Part 2
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 47 - Introduction to Quantum Mechanical Perturbation Theory
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 48 - First Order Time Independent perturbation Theory for Non-Degenerate states
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 49 - First and Second Order Time Independent Perturbation Theory for Non-Degenerate States
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 50 - First and Second Order Time Independent Perturbation Theory: Simple Examples
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 51 - Time Independent Perturbation Theory for Degenerate States: First Order
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 52 - General MO method for Homonuclear Diatomic Molecules
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 53 - General MO method for Heteronuclear Diatomic Molecules
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 54 - Introduction to Hybridization and Valence Bond for Polyatomic Molecules
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 55 - HÜckel Molecular Orbital Theory - I
Link NOC:Chemistry: Atomic Structure and Chemical Bonding Lecture 56 - HÜckel Molecular Orbital Theory - II
Link NOC:Electrochemical Impedance Spectroscopy Lecture 1 - Electrochemistry, double layer, 3 electrode systems, supporting electrolyte
Link NOC:Electrochemical Impedance Spectroscopy Lecture 2 - Rate constant, concept of impedance, Z of electrical elements, differential impedance
Link NOC:Electrochemical Impedance Spectroscopy Lecture 3 - Time domain results
Link NOC:Electrochemical Impedance Spectroscopy Lecture 4 - Graphical representation of data (Complex plane, Bode)
Link NOC:Electrochemical Impedance Spectroscopy Lecture 5 - Introduction to other techniques
Link NOC:Electrochemical Impedance Spectroscopy Lecture 6 - Tutorial 01
Link NOC:Electrochemical Impedance Spectroscopy Lecture 7 - Type of analyzers, single and multi sine
Link NOC:Electrochemical Impedance Spectroscopy Lecture 8 - FFT details, frequency range and resolution, cross correlation
Link NOC:Electrochemical Impedance Spectroscopy Lecture 9 - Multi sine, odd harmonic, non-harmonics, crest factor, spectral leakage
Link NOC:Electrochemical Impedance Spectroscopy Lecture 10 - Windowing
Link NOC:Electrochemical Impedance Spectroscopy Lecture 11 - Tutorial 02
Link NOC:Electrochemical Impedance Spectroscopy Lecture 12 - Introduction to KKT
Link NOC:Electrochemical Impedance Spectroscopy Lecture 13 - Linearity, causality, stability, impedance vs. admittance, measurement model
Link NOC:Electrochemical Impedance Spectroscopy Lecture 14 - Linear KKT illustration
Link NOC:Electrochemical Impedance Spectroscopy Lecture 15 - Tutorial 03
Link NOC:Electrochemical Impedance Spectroscopy Lecture 16 - Introduction to EEC, Choice of circuits, confidence intervals, AIC
Link NOC:Electrochemical Impedance Spectroscopy Lecture 17 - EEC fitting, initial values, distinguishability
Link NOC:Electrochemical Impedance Spectroscopy Lecture 18 - Zero/pole representation, Rt and Rp
Link NOC:Electrochemical Impedance Spectroscopy Lecture 19 - Maxwell, Voigt, Ladder circuits, choice of initial values illustrated
Link NOC:Electrochemical Impedance Spectroscopy Lecture 20 - Tutorial 04
Link NOC:Electrochemical Impedance Spectroscopy Lecture 21 - Simple electron transfer reaction
Link NOC:Electrochemical Impedance Spectroscopy Lecture 22 - Two step reaction with an intermediate (1 of 3)
Link NOC:Electrochemical Impedance Spectroscopy Lecture 23 - Two step reaction with an intermediate (2 of 3)
Link NOC:Electrochemical Impedance Spectroscopy Lecture 24 - Two step reaction with an intermediate (3 of 3)
Link NOC:Electrochemical Impedance Spectroscopy Lecture 25 - E-EAR reaction, negative resistance (1 of 2)
Link NOC:Electrochemical Impedance Spectroscopy Lecture 26 - E-EAR reaction, negative resistance (2 of 2)
Link NOC:Electrochemical Impedance Spectroscopy Lecture 27 - Three step reaction with two adsorbed intermediates
Link NOC:Electrochemical Impedance Spectroscopy Lecture 28 - Catalytic mechanism
Link NOC:Electrochemical Impedance Spectroscopy Lecture 29 - Examples with Frumkin or Temkin isotherms
Link NOC:Electrochemical Impedance Spectroscopy Lecture 30 - Challenges in RMA
Link NOC:Electrochemical Impedance Spectroscopy Lecture 31 - Patterns Reported in Experiments
Link NOC:Electrochemical Impedance Spectroscopy Lecture 32 - Warburg part - 1
Link NOC:Electrochemical Impedance Spectroscopy Lecture 33 - Warburg part - 2
Link NOC:Electrochemical Impedance Spectroscopy Lecture 34 - Warburg part - 3
Link NOC:Electrochemical Impedance Spectroscopy Lecture 35 - Bounded Warburg
Link NOC:Electrochemical Impedance Spectroscopy Lecture 36 - CPE
Link NOC:Electrochemical Impedance Spectroscopy Lecture 37 - Porous electrodes
Link NOC:Electrochemical Impedance Spectroscopy Lecture 38 - Films, PDM
Link NOC:Electrochemical Impedance Spectroscopy Lecture 39 - PDM
Link NOC:Electrochemical Impedance Spectroscopy Lecture 40 - Applications
Link NOC:Electrochemical Impedance Spectroscopy Lecture 41 - NLEIS. Introduction and mathematical background
Link NOC:Electrochemical Impedance Spectroscopy Lecture 42 - Electron Transfer reaction
Link NOC:Electrochemical Impedance Spectroscopy Lecture 43 - Two step reaction
Link NOC:Electrochemical Impedance Spectroscopy Lecture 44 - Two step reaction (Continued...)
Link NOC:Electrochemical Impedance Spectroscopy Lecture 45 - Rt and Rp estimation
Link NOC:Electrochemical Impedance Spectroscopy Lecture 46 - Galvanostatic simulations
Link NOC:Electrochemical Impedance Spectroscopy Lecture 47 - Instabilities
Link NOC:Electrochemical Impedance Spectroscopy Lecture 48 - Solution resistance effects
Link NOC:Electrochemical Impedance Spectroscopy Lecture 49 - Detection on nonlinearities using KKT
Link NOC:Electrochemical Impedance Spectroscopy Lecture 50 - Frumkin and Temkin isotherms
Link NOC:Electrochemical Impedance Spectroscopy Lecture 51 - NLEIS Experimental aspects. FFT, PSD, THD
Link NOC:Electrochemical Impedance Spectroscopy Lecture 52 - Application - other techniques HA, EFM
Link NOC:Medicinal Chemistry Lecture 1 - Introduction to Medicinal Chemistry - Part I
Link NOC:Medicinal Chemistry Lecture 2 - Introduction to Medicinal Chemistry - Part II
Link NOC:Medicinal Chemistry Lecture 3 - Intermolecular Binding Forces
Link NOC:Medicinal Chemistry Lecture 4 - Protein Structure and Function
Link NOC:Medicinal Chemistry Lecture 5 - Tutorial 1 - Acidity, Basicity and Related concepts
Link NOC:Medicinal Chemistry Lecture 6 - Tutorial 2 - Basic Concepts of Thermodynamics and Kinetics
Link NOC:Medicinal Chemistry Lecture 7 - Enzyme Catalysis - Part I
Link NOC:Medicinal Chemistry Lecture 8 - Enzyme Catalysis - Part II
Link NOC:Medicinal Chemistry Lecture 9 - Tutorial 3 - Binding Forces, Protein Structure and Function
Link NOC:Medicinal Chemistry Lecture 10 - Introduction to Receptors
Link NOC:Medicinal Chemistry Lecture 11 - Receptor Types and Functions
Link NOC:Medicinal Chemistry Lecture 12 - Tutorial 4 - Receptors, Binding Interactions, Ion Channels
Link NOC:Medicinal Chemistry Lecture 13 - Nucleic Acids
Link NOC:Medicinal Chemistry Lecture 14 - RNA and Protein Synthesis
Link NOC:Medicinal Chemistry Lecture 15 - Tutorial 5 - Nucleic acids, and Basics of Molecular Biology
Link NOC:Medicinal Chemistry Lecture 16 - Enzymes as Drug Targets
Link NOC:Medicinal Chemistry Lecture 17 - Enzyme Kinetics and Inhibition
Link NOC:Medicinal Chemistry Lecture 18 - Tutorial 6 - Enzyme Kinetics, Various Modes of Inhibition etc.
Link NOC:Medicinal Chemistry Lecture 19 - Receptors as Drug Targets - Part I
Link NOC:Medicinal Chemistry Lecture 20 - Receptors as Drug Targets - Part II
Link NOC:Medicinal Chemistry Lecture 21 - Tutorial 7 - Receptor-Drug Interactions, Stereochemistry, Chirality, Nomenclature
Link NOC:Medicinal Chemistry Lecture 22 - Receptor-Drug Interactions.
Link NOC:Medicinal Chemistry Lecture 23 - Stereochemistry and Conformation
Link NOC:Medicinal Chemistry Lecture 24 - Tutorial 8 - Determination of Drug-Receptor Interactions, Conformation of Cyclic and Acyclic Structures etc.
Link NOC:Medicinal Chemistry Lecture 25 - Nucleic Acids as Drug Targets - Part I
Link NOC:Medicinal Chemistry Lecture 26 - Nucleic Acids as Drug Targets - Part II
Link NOC:Medicinal Chemistry Lecture 27 - Miscellaneous Drug Targets
Link NOC:Medicinal Chemistry Lecture 28 - Tutorial 9 - Nucleic Acids and Related Topics
Link NOC:Medicinal Chemistry Lecture 29 - Mechanisms in Biological Chemistry - Part I
Link NOC:Medicinal Chemistry Lecture 30 - Mechanisms in Biological Chemistry - Part II
Link NOC:Medicinal Chemistry Lecture 31 - Mechanisms in Biological Chemistry - Part III
Link NOC:Medicinal Chemistry Lecture 32 - Pharmacokinetics - Part I
Link NOC:Medicinal Chemistry Lecture 33 - Pharmacokinetics - Part II
Link NOC:Medicinal Chemistry Lecture 34 - Drug Metabolism - Part I
Link NOC:Medicinal Chemistry Lecture 35 - Drug Metabolism - Part II
Link NOC:Medicinal Chemistry Lecture 36 - Drug Metabolism - Part III
Link NOC:Medicinal Chemistry Lecture 37 - Drug Metabolism - Part IV
Link NOC:Medicinal Chemistry Lecture 38 - Tutorial 10 - ADME
Link NOC:Medicinal Chemistry Lecture 39 - Drug Administration Routes - Part I
Link NOC:Medicinal Chemistry Lecture 40 - Drug Administration Routes - Part II
Link NOC:Medicinal Chemistry Lecture 41 - Finding a Lead - Part I
Link NOC:Medicinal Chemistry Lecture 42 - Finding a Lead - Part II
Link NOC:Medicinal Chemistry Lecture 43 - Drug Screening
Link NOC:Medicinal Chemistry Lecture 44 - Tutorial 11 - Drug administration routes and finding a lead
Link NOC:Medicinal Chemistry Lecture 45 - Optimizing Drug-Target Interactions - Part I
Link NOC:Medicinal Chemistry Lecture 46 - Optimizing Drug-Target Interactions - Part II
Link NOC:Medicinal Chemistry Lecture 47 - Optimizing Drug-Target Interactions - Part III
Link NOC:Medicinal Chemistry Lecture 48 - Optimizing Drug-Target Interactions - Part IV
Link NOC:Medicinal Chemistry Lecture 49 - Tutorial 12
Link NOC:Medicinal Chemistry Lecture 50 - Optimizing Access to the Target
Link NOC:Medicinal Chemistry Lecture 51 - Prodrugs
Link NOC:Medicinal Chemistry Lecture 52 - Prodrugs and Drug Alliances
Link NOC:Medicinal Chemistry Lecture 53 - Endogenous Compounds, Peptidomimetics and Oligonucleotides as Drugs
Link NOC:Medicinal Chemistry Lecture 54 - Tutorial 13- Optimizing Access-Prodrugs
Link NOC:Medicinal Chemistry Lecture 55 - Combinatorial and parallel synthesis
Link NOC:Medicinal Chemistry Lecture 56 - Computer in Medicinal Chemistry
Link NOC:Medicinal Chemistry Lecture 57 - Antibacterial agents - 1
Link NOC:Medicinal Chemistry Lecture 58 - Antibacterial agents - 2
Link NOC:Medicinal Chemistry Lecture 59 - Tutorial14-Combinatorial and parallel synthesis, computers in med chem and anti-bacterial agents
Link NOC:Medicinal Chemistry Lecture 60 - Anti-viral agents - 1
Link NOC:Medicinal Chemistry Lecture 61 - Anti-viral agents - 2
Link NOC:Medicinal Chemistry Lecture 62 - Anti-cancer agents - 1
Link NOC:Medicinal Chemistry Lecture 63 - Anti-cancer agents - 2
Link NOC:Medicinal Chemistry Lecture 64 - Cholinergics
Link NOC:Medicinal Chemistry Lecture 65 - Anti-ulcer agents
Link NOC:Medicinal Chemistry Lecture 66 - QSAR - 1
Link NOC:Medicinal Chemistry Lecture 67 - QSAR - 2
Link NOC:Medicinal Chemistry Lecture 68 - QSAR - 3
Link NOC:Medicinal Chemistry Lecture 69 - Drug Resistance and Synergy
Link NOC:Chemical Principles-II Lecture 1 - Introduction to The Thermodynamics
Link NOC:Chemical Principles-II Lecture 2 - History of Thermodynamic
Link NOC:Chemical Principles-II Lecture 3 - Thermodynamic Systems and Variables
Link NOC:Chemical Principles-II Lecture 4 - Zeroth Law of Thermodynamic
Link NOC:Chemical Principles-II Lecture 5 - Microscopic Definition of Temperature - Part 1
Link NOC:Chemical Principles-II Lecture 6 - Microscopic Definition of Temperature - Part 2
Link NOC:Chemical Principles-II Lecture 7 - Different Forms of Energy
Link NOC:Chemical Principles-II Lecture 8 - Real Gas and Virial Equation
Link NOC:Chemical Principles-II Lecture 9 - Van der Waals Gas
Link NOC:Chemical Principles-II Lecture 10 - Work and Heat - Part 1
Link NOC:Chemical Principles-II Lecture 11 - Work and Heat - Part 2
Link NOC:Chemical Principles-II Lecture 12 - First Law of Thermodynamics
Link NOC:Chemical Principles-II Lecture 13 - Microscopic Definition of Heat and Work
Link NOC:Chemical Principles-II Lecture 14 - Work done at a Constant Temperature
Link NOC:Chemical Principles-II Lecture 15 - Heat is a path function
Link NOC:Chemical Principles-II Lecture 16 - Joule-Thomson Effect (For Ideal Gases)
Link NOC:Chemical Principles-II Lecture 17 - Joule-Thomson Effect (For Van der Waals gas)
Link NOC:Chemical Principles-II Lecture 18 - Adiabatic Reversible Work
Link NOC:Chemical Principles-II Lecture 19 - Adiabatic Irreversible Work
Link NOC:Chemical Principles-II Lecture 20 - Tutorial Problem - 1
Link NOC:Chemical Principles-II Lecture 21 - Tutorial Problem - 2
Link NOC:Chemical Principles-II Lecture 22 - Thermochemistry - Part 1
Link NOC:Chemical Principles-II Lecture 23 - Thermochemistry - Part 2
Link NOC:Chemical Principles-II Lecture 24 - Second Law of Thermodynamics
Link NOC:Chemical Principles-II Lecture 25 - Statements of the Second Law of Thermodynamics
Link NOC:Chemical Principles-II Lecture 26 - Carnot Cycle and Definition of Entropy
Link NOC:Chemical Principles-II Lecture 27 - Ideal Stirling Engine
Link NOC:Chemical Principles-II Lecture 28 - Gasoline Engine and Diesel Engine
Link NOC:Chemical Principles-II Lecture 29 - Carnot’ Cycle: The Most Efficient Engine
Link NOC:Chemical Principles-II Lecture 30 - Thermodynamic Temperature
Link NOC:Chemical Principles-II Lecture 31 - Definition of Entropy
Link NOC:Chemical Principles-II Lecture 32 - Tutorial Problem - 3
Link NOC:Chemical Principles-II Lecture 33 - Tutorial Problem - 4
Link NOC:Chemical Principles-II Lecture 34 - Tutorial Problem - 5
Link NOC:Chemical Principles-II Lecture 35 - Tutorial Problem - 6
Link NOC:Chemical Principles-II Lecture 36 - Tutorial Problem - 7
Link NOC:Chemical Principles-II Lecture 37 - Tutorial Problem - 8
Link NOC:Chemical Principles-II Lecture 38 - Statistical Formulation of the Second Law
Link NOC:Chemical Principles-II Lecture 39 - Probability
Link NOC:Chemical Principles-II Lecture 40 - Microstates and Distributions
Link NOC:Chemical Principles-II Lecture 41 - Permutation and Combination
Link NOC:Chemical Principles-II Lecture 42 - Two-Level Systems
Link NOC:Chemical Principles-II Lecture 43 - Most Probable Distribution
Link NOC:Chemical Principles-II Lecture 44 - Calculation with Multi-Level systems
Link NOC:Chemical Principles-II Lecture 45 - Calculation with Multi-Level systems with fixed energy - Part 1
Link NOC:Chemical Principles-II Lecture 46 - Calculation with Multi-Level systems with fixed energy - Part 2
Link NOC:Chemical Principles-II Lecture 47 - Calculation with Multi-Level systems with fixed energy - Part 3
Link NOC:Chemical Principles-II Lecture 48 - Bose-Einstein, Fermi-Dirac and Maxwell-Boltzmann distribution
Link NOC:Chemical Principles-II Lecture 49 - Most Probable Distribution is the Boltzmann Distribution
Link NOC:Chemical Principles-II Lecture 50 - Demonstration of Boltzmann Distribution
Link NOC:Chemical Principles-II Lecture 51 - Estimating Entropy for Various Processes
Link NOC:Chemical Principles-II Lecture 52 - Microscopic equivalent of Heat and Work
Link NOC:Chemical Principles-II Lecture 53 - Probability and Boltzmann Distribution
Link NOC:Chemical Principles-II Lecture 54 - Thermodynamic Observables: It is all in the Average
Link NOC:Chemical Principles-II Lecture 55 - Tutorial Problem - 9
Link NOC:Chemical Principles-II Lecture 56 - Tutorial Problem - 10
Link NOC:Chemical Principles-II Lecture 57 - Tutorial Problem - 11
Link NOC:Chemical Principles-II Lecture 58 - Tutorial Problem - 12
Link NOC:Chemical Principles-II Lecture 59 - Thermodynamic free energy
Link NOC:Chemical Principles-II Lecture 60 - Condition for Spontaneity
Link NOC:Chemical Principles-II Lecture 61 - Legendre Transformation of Thermodynamic Potentials
Link NOC:Chemical Principles-II Lecture 62 - Maxwell Relations and Applications
Link NOC:Chemical Principles-II Lecture 63 - Thermodynamic Relations using Jacobian Method - Part 1
Link NOC:Chemical Principles-II Lecture 64 - Thermodynamic Relations using Jacobian Method - Part 2
Link NOC:Chemical Principles-II Lecture 65 - Tutorial Problem - 13
Link NOC:Chemical Principles-II Lecture 66 - Tutorial Problem - 14
Link NOC:Chemical Principles-II Lecture 67 - Tutorial Problem - 15
Link NOC:Chemical Principles-II Lecture 68 - Tutorial Problem - 16
Link NOC:Chemical Principles-II Lecture 69 - Chemical Principle II - Overview and Road Ahead
Link Organic Chemistry Lab Certification Lecture 1 - Feedback on Techniques in Organic Chemistry
Link Organic Chemistry Lab Certification Lecture 2 - Introduction to Claesen - Condensation
Link Organic Chemistry Lab Certification Lecture 3 - Introduction to Claesen - Condensation
Link Organic Chemistry Lab Certification Lecture 4 - How to separate different components from a mixture using column chromatography
Link Organic Chemistry Lab Certification Lecture 5 - Flurescence phenomenon
Link Organic Chemistry Lab Certification Lecture 6 - Reaction Mechanism and Sterochemistry
Link Organic Chemistry Lab Certification Lecture 7 - Chemiluminescence Phenomenon
Link Organic Chemistry Lab Certification Lecture 8 - Post Lab Questions
Link NOC:Introductory Organic Chemistry-I Lecture 1 - Introduction Structure of atom and molecules
Link NOC:Introductory Organic Chemistry-I Lecture 2 - Introduction to Molecular Orbital Theory - Part 1
Link NOC:Introductory Organic Chemistry-I Lecture 3 - Introduction to Molecular Orbital Theory - Part 2
Link NOC:Introductory Organic Chemistry-I Lecture 4 - Tutorial 01
Link NOC:Introductory Organic Chemistry-I Lecture 5 - Learning Objectives for week 2
Link NOC:Introductory Organic Chemistry-I Lecture 6 - Alkanes and Cycloalkanes - Part 1
Link NOC:Introductory Organic Chemistry-I Lecture 7 - Alkanes and Cycloalkanes - Part 2
Link NOC:Introductory Organic Chemistry-I Lecture 8 - Conformational Analysis of Cyclohexane - Part 1
Link NOC:Introductory Organic Chemistry-I Lecture 9 - Conformational Analysis of Cyclohexane - Part 2
Link NOC:Introductory Organic Chemistry-I Lecture 10 - Physical Properties of Alkanes
Link NOC:Introductory Organic Chemistry-I Lecture 11 - Nomenclature of Alkanes, Cycloalkanes and Bicycloalkanes
Link NOC:Introductory Organic Chemistry-I Lecture 12 - Tutorial 02
Link NOC:Introductory Organic Chemistry-I Lecture 13 - Learning Objectives for week 3
Link NOC:Introductory Organic Chemistry-I Lecture 14 - Chirality and Stereochemistry - Part 1
Link NOC:Introductory Organic Chemistry-I Lecture 15 - Chirality and Stereochemistry - Part 2
Link NOC:Introductory Organic Chemistry-I Lecture 16 - Chirality and Stereochemistry - Part 3
Link NOC:Introductory Organic Chemistry-I Lecture 17 - Tutorial 03
Link NOC:Introductory Organic Chemistry-I Lecture 18 - Learning Objectives for week 4
Link NOC:Introductory Organic Chemistry-I Lecture 19 - Acids and Bases - Part 1
Link NOC:Introductory Organic Chemistry-I Lecture 20 - Acids and Bases - Part 2
Link NOC:Introductory Organic Chemistry-I Lecture 21 - Acids and Bases - Part 3
Link NOC:Introductory Organic Chemistry-I Lecture 22 - Tutorial 04
Link NOC:Introductory Organic Chemistry-I Lecture 23 - Learning Objectives for week 5
Link NOC:Introductory Organic Chemistry-I Lecture 24 - Arrow Pushing mechanism in Organic Chemistry
Link NOC:Introductory Organic Chemistry-I Lecture 25 - Alkenes_Structure, Properties and Nomenclature
Link NOC:Introductory Organic Chemistry-I Lecture 26 - Reactions of Alkenes - Part 1
Link NOC:Introductory Organic Chemistry-I Lecture 27 - Reactions of Alkenes - Part 2
Link NOC:Introductory Organic Chemistry-I Lecture 28 - Reactions of Alkenes - Part 3
Link NOC:Introductory Organic Chemistry-I Lecture 29 - Tutorial 05 - Part 1
Link NOC:Introductory Organic Chemistry-I Lecture 30 - Tutorial 05 - Part 2
Link NOC:Introductory Organic Chemistry-I Lecture 31 - Learning Objectives for week 6
Link NOC:Introductory Organic Chemistry-I Lecture 32 - Reactions of Alkenes - Part 4
Link NOC:Introductory Organic Chemistry-I Lecture 33 - Reactions of Alkenes - Part 5
Link NOC:Introductory Organic Chemistry-I Lecture 34 - Alkynes
Link NOC:Introductory Organic Chemistry-I Lecture 35 - Reactions of Alkynes - Part 1
Link NOC:Introductory Organic Chemistry-I Lecture 36 - Reactions of Alkynes - Part 2
Link NOC:Introductory Organic Chemistry-I Lecture 37 - Tutorial-6
Link NOC:Introductory Organic Chemistry-I Lecture 38 - Learning Objectives for week 7
Link NOC:Introductory Organic Chemistry-I Lecture 39 - Substitution and Elimination - Part 1
Link NOC:Introductory Organic Chemistry-I Lecture 40 - Substitution and Elimination - Part 2
Link NOC:Introductory Organic Chemistry-I Lecture 41 - Substitution and Elimination - Part 3
Link NOC:Introductory Organic Chemistry-I Lecture 42 - Substitution and Elimination - Part 4
Link NOC:Introductory Organic Chemistry-I Lecture 43 - Substitution and Elimination - Part 5
Link NOC:Introductory Organic Chemistry-I Lecture 44 - Tutorial-7
Link NOC:Introductory Organic Chemistry-I Lecture 45 - Learning Objectives for week 8
Link NOC:Introductory Organic Chemistry-I Lecture 46 - Alcohols - Part 1
Link NOC:Introductory Organic Chemistry-I Lecture 47 - Alcohols - Part 2
Link NOC:Introductory Organic Chemistry-I Lecture 48 - Alcohols - Part 3
Link NOC:Introductory Organic Chemistry-I Lecture 49 - Ethers and Epoxides - Part 1
Link NOC:Introductory Organic Chemistry-I Lecture 50 - Ethers and Epoxides - Part 2
Link NOC:Introductory Organic Chemistry-I Lecture 51 - Aromaticity
Link NOC:Introductory Organic Chemistry-I Lecture 52 - Tutorial-8
Link NOC:Quantitative Methods in Chemistry Lecture 1 - A brief history of the beginnings of quantitation in Chemistry, defining chemical stoichiometry and molarity
Link NOC:Quantitative Methods in Chemistry Lecture 2 - Defining Molality and Normality, relationship with Molarity
Link NOC:Quantitative Methods in Chemistry Lecture 3 - Defining other parameters for concentration (%, ppm/ppb, p-value)
Link NOC:Quantitative Methods in Chemistry Lecture 4 - Relationship between various concentration parameters
Link NOC:Quantitative Methods in Chemistry Lecture 5 - Problems on acid-base equilibria, calculation of pH of strong and weak acids
Link NOC:Quantitative Methods in Chemistry Lecture 6 - Brief introduction to normal distribution and statistical analysis
Link NOC:Quantitative Methods in Chemistry Lecture 7 - Using a spreadsheet towards basic statistical analysis, exact equation of error propagation, accuracy and precision
Link NOC:Quantitative Methods in Chemistry Lecture 8 - Error propagation and its application to a few examples, significant figures
Link NOC:Quantitative Methods in Chemistry Lecture 9 - Introduction to use spreadsheets to analyze errors, reiteration of significant figures, repeats and reproducibility
Link NOC:Quantitative Methods in Chemistry Lecture 10 - Classification of errors
Link NOC:Quantitative Methods in Chemistry Lecture 11 - A look at uncertainties in a measurement taking an example
Link NOC:Quantitative Methods in Chemistry Lecture 12 - A comprehensive and step-wise look at an experimental protocol towards understanding systematic errors in an experiment
Link NOC:Quantitative Methods in Chemistry Lecture 13 - Introductory Statistics - Part 1
Link NOC:Quantitative Methods in Chemistry Lecture 14 - Introductory Statistics - Part 2
Link NOC:Quantitative Methods in Chemistry Lecture 15 - Hypothesis testing and Finding Outliers - Part 1
Link NOC:Quantitative Methods in Chemistry Lecture 16 - Hypothesis testing and Finding Outliers - Part 2
Link NOC:Quantitative Methods in Chemistry Lecture 17 - Pooling of data
Link NOC:Quantitative Methods in Chemistry Lecture 18 - Introduction to Analysis of Variance (ANOVA) and comparing precisions
Link NOC:Quantitative Methods in Chemistry Lecture 19 - Protocol for undertaking ANOVA - Part 1
Link NOC:Quantitative Methods in Chemistry Lecture 20 - Protocol for undertaking ANOVA - Part 2
Link NOC:Quantitative Methods in Chemistry Lecture 21 - ANOVA and Least Significant Difference (LSD)
Link NOC:Quantitative Methods in Chemistry Lecture 22 - ANOVA and solved Least Significant Difference example
Link NOC:Quantitative Methods in Chemistry Lecture 23 - Using spreadsheet software to perform data analysis towards calibrating a burette
Link NOC:Quantitative Methods in Chemistry Lecture 24 - Using spreadsheet to analyze linear dependence between two variables
Link NOC:Quantitative Methods in Chemistry Lecture 25 - Using spreadsheet and MATLAB towards data analysis with example of rate kinetics
Link NOC:Quantitative Methods in Chemistry Lecture 26 - Simulating simple straight lines and kinetic curves using MATLAB
Link NOC:Quantitative Methods in Chemistry Lecture 27 - Simulating the Michaelis Menten kinetics using MATLAB
Link NOC:Quantitative Methods in Chemistry Lecture 28 - Curve fitting and simulating with variance for the Michaelis Menten kinetics using MATLAB
Link NOC:Quantitative Methods in Chemistry Lecture 29 - Standards and Volumetric/Gravimetric titrations - Part 1
Link NOC:Quantitative Methods in Chemistry Lecture 30 - Standards and Volumetric/Gravimetric titrations - Part 2
Link NOC:Quantitative Methods in Chemistry Lecture 31 - Standards and Volumetric/Gravimetric titrations - Part 3
Link NOC:Quantitative Methods in Chemistry Lecture 32 - Standards and Volumetric/Gravimetric titrations - Part 4
Link NOC:Quantitative Methods in Chemistry Lecture 33 - Standards and Volumetric/Gravimetric titrations - Part 5
Link NOC:Quantitative Methods in Chemistry Lecture 34 - Analytical Separations - Multistage extractions - Part 1
Link NOC:Quantitative Methods in Chemistry Lecture 35 - Analytical Separations - Multistage extractions - Part 2
Link NOC:Quantitative Methods in Chemistry Lecture 36 - Analytical Separations - Chromatography - Part 1
Link NOC:Quantitative Methods in Chemistry Lecture 37 - Analytical Separations - Chromatography - Part 2
Link NOC:Quantitative Methods in Chemistry Lecture 38 - Analytical Separations - Electrophoresis, Capillary electrophoresis, Isoelectric Focusing
Link NOC:Quantitative Methods in Chemistry Lecture 39 - Basics of Chromatography - Part 1
Link NOC:Quantitative Methods in Chemistry Lecture 40 - Basics of Chromatography - Part 2
Link NOC:Quantitative Methods in Chemistry Lecture 41 - Chromatography - Concept of Theoretical plates
Link NOC:Quantitative Methods in Chemistry Lecture 42 - Chromatography - Rate Theory
Link NOC:Quantitative Methods in Chemistry Lecture 43 - Practice of Chromatography - HPLC
Link NOC:Quantitative Methods in Chemistry Lecture 44 - Practice of Chromatography - Gas Chromatography
Link NOC:Quantitative Methods in Chemistry Lecture 45 - Supercritical Fluid Chromatography
Link NOC:Quantitative Methods in Chemistry Lecture 46 - Detectors employed during chromatographic separations
Link NOC:Quantitative Methods in Chemistry Lecture 47 - Course Revision
Link NOC:Quantitative Methods in Chemistry Lecture 48 - Course Revision - Week 1 to 3
Link NOC:Quantitative Methods in Chemistry Lecture 49 - Course Revision - Week 4 and 5
Link NOC:Quantitative Methods in Chemistry Lecture 50 - Course Revision - Week 6 and 7
Link NOC:Quantitative Methods in Chemistry Lecture 51 - Course Revision - Week 8 to 11
Link NOC:Fundamentals of Spectroscopy Lecture 1 - Introduction to Spectroscopy
Link NOC:Fundamentals of Spectroscopy Lecture 2 - Introduction to Quantum Mechanics - I
Link NOC:Fundamentals of Spectroscopy Lecture 3 - Introduction to Quantum Mechanics - II
Link NOC:Fundamentals of Spectroscopy Lecture 4 - A Simple Quantum Mechanical System: Particle in a one Dimensional Box
Link NOC:Fundamentals of Spectroscopy Lecture 5 - Spectroscopic Transitions
Link NOC:Fundamentals of Spectroscopy Lecture 6 - Intensity of a Transtion Depends on the Transition Dipole Moment - I
Link NOC:Fundamentals of Spectroscopy Lecture 7 - Intensity of a Transtion Depends on the Transition Dipole Moment - II
Link NOC:Fundamentals of Spectroscopy Lecture 8 - Comparision between Chemical Reactions and Spectroscopic Transitions
Link NOC:Fundamentals of Spectroscopy Lecture 9 - Lineshape Analysis
Link NOC:Fundamentals of Spectroscopy Lecture 10 - Different Forms of Spectroscopy
Link NOC:Fundamentals of Spectroscopy Lecture 11 - Spectroscopic Timescales
Link NOC:Fundamentals of Spectroscopy Lecture 12 - Correspondence between Linear Motion and Rotational Motion
Link NOC:Fundamentals of Spectroscopy Lecture 13 - Diatomic Rigid Rotor
Link NOC:Fundamentals of Spectroscopy Lecture 14 - Selection Rules and Rotational Spectrum
Link NOC:Fundamentals of Spectroscopy Lecture 15 - Isotope effect
Link NOC:Fundamentals of Spectroscopy Lecture 16 - Degeneracy
Link NOC:Fundamentals of Spectroscopy Lecture 17 - Intensities of Rotational Lines
Link NOC:Fundamentals of Spectroscopy Lecture 18 - Non Rigid Rotor
Link NOC:Fundamentals of Spectroscopy Lecture 19 - Polyatomic Molecules - I
Link NOC:Fundamentals of Spectroscopy Lecture 20 - Polyatomic Molecules - II and Numericals
Link NOC:Fundamentals of Spectroscopy Lecture 21 - Origin of the Rotational Selection Rule
Link NOC:Fundamentals of Spectroscopy Lecture 22 - Simple Harmonic Oscillator
Link NOC:Fundamentals of Spectroscopy Lecture 23 - Energy Levels
Link NOC:Fundamentals of Spectroscopy Lecture 24 - Selection Rules
Link NOC:Fundamentals of Spectroscopy Lecture 25 - Anharmonicity
Link NOC:Fundamentals of Spectroscopy Lecture 26 - Effects of Anharmonicity
Link NOC:Fundamentals of Spectroscopy Lecture 27 - Ro-vibrational Spectrum - I
Link NOC:Fundamentals of Spectroscopy Lecture 28 - Ro-vibrational Spectrum - II
Link NOC:Fundamentals of Spectroscopy Lecture 29 - Harmonic Oscillator Eigenvalues and Eigenfunctions - I
Link NOC:Fundamentals of Spectroscopy Lecture 30 - Harmonic Oscillator Eigenvalues and Eigenfunctions - II
Link NOC:Fundamentals of Spectroscopy Lecture 31 - Vibration of a Diatomic Molecule and Derivation of the Vibrational Selection Rule
Link NOC:Fundamentals of Spectroscopy Lecture 32 - Ro-vibrational Spectrum - III
Link NOC:Fundamentals of Spectroscopy Lecture 33 - Vibration of Polyatomic Molecules - I
Link NOC:Fundamentals of Spectroscopy Lecture 34 - Vibration of Polyatomic Molecules - II
Link NOC:Fundamentals of Spectroscopy Lecture 35 - Vibration of Polyatomic Molecules - III
Link NOC:Fundamentals of Spectroscopy Lecture 36 - Normal Mode Coordinates
Link NOC:Fundamentals of Spectroscopy Lecture 37 - Introduction to Raman Spectroscopy
Link NOC:Fundamentals of Spectroscopy Lecture 38 - Quantum theory of Raman effect
Link NOC:Fundamentals of Spectroscopy Lecture 39 - Rotational Raman Spectroscopy
Link NOC:Fundamentals of Spectroscopy Lecture 40 - Nuclear Spin Statistics
Link NOC:Fundamentals of Spectroscopy Lecture 41 - Polarizability and Polarizability Ellipsoid
Link NOC:Fundamentals of Spectroscopy Lecture 42 - Raman Activity of Vibrations
Link NOC:Fundamentals of Spectroscopy Lecture 43 - Vibrational Raman Spectroscopy
Link NOC:Fundamentals of Spectroscopy Lecture 44 - Polarization Effects and Numericals
Link NOC:Fundamentals of Spectroscopy Lecture 45 - Resonance Spectroscopy - Introduction 1
Link NOC:Fundamentals of Spectroscopy Lecture 46 - Resonance Spectroscopy - Introduction 2
Link NOC:Fundamentals of Spectroscopy Lecture 47 - NMR Spectroscopy - 1
Link NOC:Fundamentals of Spectroscopy Lecture 48 - NMR Spectroscopy - 2
Link NOC:Fundamentals of Spectroscopy Lecture 49 - NMR Spectroscopy - 3
Link NOC:Fundamentals of Spectroscopy Lecture 50 - NMR Spectroscopy - 4
Link NOC:Fundamentals of Spectroscopy Lecture 51 - NMR Spectroscopy - 5
Link NOC:Fundamentals of Spectroscopy Lecture 52 - NMR Spectroscopy - 6
Link NOC:Fundamentals of Spectroscopy Lecture 53 - ESR Spectroscopy - 1
Link NOC:Fundamentals of Spectroscopy Lecture 54 - ESR Spectroscopy - 2
Link NOC:Fundamentals of Spectroscopy Lecture 55 - ESR Spectroscopy - 3
Link NOC:Fundamentals of Spectroscopy Lecture 56 - ESR Spectroscopy - 4
Link NOC:Fundamentals of Spectroscopy Lecture 57 - Electronic Spectroscopy - 1
Link NOC:Fundamentals of Spectroscopy Lecture 58 - Electronic Spectroscopy - 2
Link NOC:Fundamentals of Spectroscopy Lecture 59 - Electronic Spectroscopy - 3
Link NOC:Fundamentals of Spectroscopy Lecture 60 - Electronic Spectroscopy - 4
Link NOC:Fundamentals of Spectroscopy Lecture 61 - Electronic Spectroscopy - 5
Link NOC:Symmetry, Stereochemistry and Applications Lecture 1 - Introduction to stereochemistry
Link NOC:Symmetry, Stereochemistry and Applications Lecture 2 - Nomenclature of Various Organic Molecules
Link NOC:Symmetry, Stereochemistry and Applications Lecture 3 - Nomenclature of Cyclic molecules and other functional groups
Link NOC:Symmetry, Stereochemistry and Applications Lecture 4 - Nomenclature of some complex molecules
Link NOC:Symmetry, Stereochemistry and Applications Lecture 5 - Practising naming of molecules
Link NOC:Symmetry, Stereochemistry and Applications Lecture 6 - Symmetry, Stereochemistry and Applications
Link NOC:Symmetry, Stereochemistry and Applications Lecture 7 - Symmetry elements in organic molecules
Link NOC:Symmetry, Stereochemistry and Applications Lecture 8 - Molecular point groups - Part I
Link NOC:Symmetry, Stereochemistry and Applications Lecture 9 - Molecular point groups - Part II
Link NOC:Symmetry, Stereochemistry and Applications Lecture 10 - Conformations and Configurations
Link NOC:Symmetry, Stereochemistry and Applications Lecture 11 - Conformational Analysis - Part I
Link NOC:Symmetry, Stereochemistry and Applications Lecture 12 - Conformational Analysis - Part II
Link NOC:Symmetry, Stereochemistry and Applications Lecture 13 - Chair and Boat Conformation of Cyclohexane
Link NOC:Symmetry, Stereochemistry and Applications Lecture 14 - Conformational Analysis of Disubstituted Cyclohexane Molecules
Link NOC:Symmetry, Stereochemistry and Applications Lecture 15 - Isomerism and Representation of Isomers
Link NOC:Symmetry, Stereochemistry and Applications Lecture 16 - Stereoisomerism
Link NOC:Symmetry, Stereochemistry and Applications Lecture 17 - Drawing One Projection from Another
Link NOC:Symmetry, Stereochemistry and Applications Lecture 18 - Optical Activity of Organic Molecules and Isomerism
Link NOC:Symmetry, Stereochemistry and Applications Lecture 19 - Allenes and Biphenyls
Link NOC:Symmetry, Stereochemistry and Applications Lecture 20 - Absolute Configuration in Biphenyls and D/L Systems
Link NOC:Symmetry, Stereochemistry and Applications Lecture 21 - Asymmetry and Dissymmetry Molecules
Link NOC:Symmetry, Stereochemistry and Applications Lecture 22 - Stereoisomerism and Local Symmetry
Link NOC:Symmetry, Stereochemistry and Applications Lecture 23 - Topicity of Ligands
Link NOC:Symmetry, Stereochemistry and Applications Lecture 24 - Topicity of Faces
Link NOC:Symmetry, Stereochemistry and Applications Lecture 25 - Problems on Isomers and Topicity
Link NOC:Symmetry, Stereochemistry and Applications Lecture 26 - Diastereomerism in Ring System - Part 1
Link NOC:Symmetry, Stereochemistry and Applications Lecture 27 - Diastereomerism in Ring System - Part 2
Link NOC:Symmetry, Stereochemistry and Applications Lecture 28 - Diastereomerism in Ring System - Part 3
Link NOC:Symmetry, Stereochemistry and Applications Lecture 29 - Diastereomerism in PI System
Link NOC:Symmetry, Stereochemistry and Applications Lecture 30 - Nucleophilic Reactions
Link NOC:Symmetry, Stereochemistry and Applications Lecture 31 - Mechanism of Nucleophilic Substitution Reaction
Link NOC:Symmetry, Stereochemistry and Applications Lecture 32 - Stability of Carbocation
Link NOC:Symmetry, Stereochemistry and Applications Lecture 33 - Elimination Reactions
Link NOC:Symmetry, Stereochemistry and Applications Lecture 34 - Substitution VS Elimination Reactions
Link NOC:Symmetry, Stereochemistry and Applications Lecture 35 - Addition Reactions to Alkenes and Alkynes - Part 1
Link NOC:Symmetry, Stereochemistry and Applications Lecture 36 - Addition Reactions to Alkenes and Alkynes - Part 2
Link NOC:Symmetry, Stereochemistry and Applications Lecture 37 - Oxidizing Agents in Organic Chemistry and Organometallic Compounds
Link NOC:Symmetry, Stereochemistry and Applications Lecture 38 - Some Problems and their Answers in Stereochemistry
Link NOC:Symmetry, Stereochemistry and Applications Lecture 39 - Dynamic Stereochemistry - Part 1
Link NOC:Symmetry, Stereochemistry and Applications Lecture 40 - Dynamic Stereochemistry - Part 2
Link NOC:Symmetry, Stereochemistry and Applications Lecture 41 - Reaction Specificity and Selectivity
Link NOC:Symmetry, Stereochemistry and Applications Lecture 42 - Cram's Rule and Felkin-Anh Model
Link NOC:Symmetry, Stereochemistry and Applications Lecture 43 - Kinetics of Organic Reactions
Link NOC:Symmetry, Stereochemistry and Applications Lecture 44 - Name Reactions and Their Mechanism - Part 1
Link NOC:Symmetry, Stereochemistry and Applications Lecture 45 - Name Reactions and Their Mechanism - Part 2
Link NOC:Symmetry, Stereochemistry and Applications Lecture 46 - Modifications of Diels-Alder Reaction
Link NOC:Symmetry, Stereochemistry and Applications Lecture 47 - Name Reactions and Their Mechanism - Part 3
Link NOC:Symmetry, Stereochemistry and Applications Lecture 48 - Name Reactions and Their Mechanism - Part 4
Link NOC:Symmetry, Stereochemistry and Applications Lecture 49 - Rearrangement Reactions in Organic Chemistry - Part 1
Link NOC:Symmetry, Stereochemistry and Applications Lecture 50 - Rearrangement Reactions in Organic Chemistry - Part 2
Link NOC:Symmetry, Stereochemistry and Applications Lecture 51 - Rearrangement Reactions in Organic Chemistry - Part 3
Link NOC:Symmetry, Stereochemistry and Applications Lecture 52 - Rearrangement Reactions in Organic Chemistry - Part 4
Link NOC:Symmetry, Stereochemistry and Applications Lecture 53 - Brief introduction to crystallographic symmetry
Link NOC:Symmetry, Stereochemistry and Applications Lecture 54 - Symmetries in X-ray Crystallography
Link NOC:Symmetry, Stereochemistry and Applications Lecture 55 - 2D lattices and space groups
Link NOC:Symmetry, Stereochemistry and Applications Lecture 56 - 3D crystallographic point groups and space groups
Link NOC:Symmetry and Group Theory (2021) Lecture 1 - Course Contents
Link NOC:Symmetry and Group Theory (2021) Lecture 2 - Symmetry and Parity Operator
Link NOC:Symmetry and Group Theory (2021) Lecture 3 - Symmetry Elements and Operations - Part 1
Link NOC:Symmetry and Group Theory (2021) Lecture 4 - Symmetry Elements and Operations - Part 2
Link NOC:Symmetry and Group Theory (2021) Lecture 5 - Planes and Reflections
Link NOC:Symmetry and Group Theory (2021) Lecture 6 - Tutorial - 1
Link NOC:Symmetry and Group Theory (2021) Lecture 7 - Coordinate System and Inversion Center
Link NOC:Symmetry and Group Theory (2021) Lecture 8 - Improper axis and improper rotation
Link NOC:Symmetry and Group Theory (2021) Lecture 9 - Solved Examples of Symmetry Elements and Operations
Link NOC:Symmetry and Group Theory (2021) Lecture 10 - Product of Symmetry Operations
Link NOC:Symmetry and Group Theory (2021) Lecture 11 - Tutorial - 2
Link NOC:Symmetry and Group Theory (2021) Lecture 12 - Symmetry Point Groups - Part 1
Link NOC:Symmetry and Group Theory (2021) Lecture 13 - Symmetry Point Groups - Part 2
Link NOC:Symmetry and Group Theory (2021) Lecture 14 - Symmetry Point Groups - Part 3
Link NOC:Symmetry and Group Theory (2021) Lecture 15 - Dipole Moment and Optical Acitivity
Link NOC:Symmetry and Group Theory (2021) Lecture 16 - Tutorial - 3
Link NOC:Symmetry and Group Theory (2021) Lecture 17 - Point Group Definition and Examples
Link NOC:Symmetry and Group Theory (2021) Lecture 18 - Sub-Group and Classes
Link NOC:Symmetry and Group Theory (2021) Lecture 19 - Matrix Representation of Symmetry Operations
Link NOC:Symmetry and Group Theory (2021) Lecture 20 - Matrix Representation of Point Group
Link NOC:Symmetry and Group Theory (2021) Lecture 21 - Tutorial - 4
Link NOC:Symmetry and Group Theory (2021) Lecture 22 - Matrix Representation of Point Group
Link NOC:Symmetry and Group Theory (2021) Lecture 23 - Reducible and Irreducible Representations
Link NOC:Symmetry and Group Theory (2021) Lecture 24 - Great Orthogonality Theorem
Link NOC:Symmetry and Group Theory (2021) Lecture 25 - Properties of Great Orthogonality Theorem
Link NOC:Symmetry and Group Theory (2021) Lecture 26 - Tutorial - 5
Link NOC:Symmetry and Group Theory (2021) Lecture 27 - Irreducible Representation using GOT
Link NOC:Symmetry and Group Theory (2021) Lecture 28 - Reducible to Irreducible Representation using GoT
Link NOC:Symmetry and Group Theory (2021) Lecture 29 - Character Table and Mulliken Symbols
Link NOC:Symmetry and Group Theory (2021) Lecture 30 - How to write a complete character table
Link NOC:Symmetry and Group Theory (2021) Lecture 31 - Tutorial - 6
Link NOC:Symmetry and Group Theory (2021) Lecture 32 - Representations of a cyclic group
Link NOC:Symmetry and Group Theory (2021) Lecture 33 - Group Theory and Quantum Mechanics
Link NOC:Symmetry and Group Theory (2021) Lecture 34 - 1) Degenerate Eigen Functions 2) Direct Product
Link NOC:Symmetry and Group Theory (2021) Lecture 35 - Direct Product
Link NOC:Symmetry and Group Theory (2021) Lecture 36 - Tutorial - 7
Link NOC:Symmetry and Group Theory (2021) Lecture 37 - Direct Product Applications - Part 1
Link NOC:Symmetry and Group Theory (2021) Lecture 38 - Direct Product Applications - Part 2
Link NOC:Symmetry and Group Theory (2021) Lecture 39 - Symmetry Adapted Linear Combinations - Part 1
Link NOC:Symmetry and Group Theory (2021) Lecture 40 - Symmetry Adapted Linear Combinations - Part 2
Link NOC:Symmetry and Group Theory (2021) Lecture 41 - Tutorial - 8
Link NOC:Symmetry and Group Theory (2021) Lecture 42 - Incomplete Projection Operator
Link NOC:Symmetry and Group Theory (2021) Lecture 43 - SALC using Projection Operator
Link NOC:Symmetry and Group Theory (2021) Lecture 44 - Symmetry and Chemical Bonding
Link NOC:Symmetry and Group Theory (2021) Lecture 45 - Valence Bond Theory
Link NOC:Symmetry and Group Theory (2021) Lecture 46 - Tutorial - 9
Link NOC:Symmetry and Group Theory (2021) Lecture 47 - Molecular Orbital Theory
Link NOC:Symmetry and Group Theory (2021) Lecture 48 - Localised MO Theory
Link NOC:Symmetry and Group Theory (2021) Lecture 49 - Delocalized MO Theory - Part 1
Link NOC:Symmetry and Group Theory (2021) Lecture 50 - Delocalized MO Theory - Part 2
Link NOC:Symmetry and Group Theory (2021) Lecture 51 - Ascent and Descent in Symmetry - Part 1
Link NOC:Symmetry and Group Theory (2021) Lecture 52 - Ascent and Descent in Symmetry - Part 2
Link NOC:Symmetry and Group Theory (2021) Lecture 53 - Crystal Field Theory - Part 1
Link NOC:Symmetry and Group Theory (2021) Lecture 54 - Crystal Field Theory - Part 2
Link NOC:Symmetry and Group Theory (2021) Lecture 55 - Jahn-Teller Distortion - Part 1
Link NOC:Symmetry and Group Theory (2021) Lecture 56 - Jahn-Teller Distortion - Part 2
Link NOC:Symmetry and Group Theory (2021) Lecture 57 - Introduction to Spectroscopy - Part 1
Link NOC:Symmetry and Group Theory (2021) Lecture 58 - Introduction to Spectroscopy - Part 2
Link NOC:Symmetry and Group Theory (2021) Lecture 59 - Vibrational Spectroscopy
Link NOC:Symmetry and Group Theory (2021) Lecture 60 - 1) Raman Spectroscopy and 2) Atomic Motions
Link NOC:Symmetry and Group Theory (2021) Lecture 61 - Symmetry of Normal Modes of Vibration
Link NOC:Symmetry and Group Theory (2021) Lecture 62 - Visualizing Molecular Vibrations using Internal Coordinates
Link NOC:Symmetry and Group Theory (2021) Lecture 63 - Spectral Transition Probabilities - Part 1
Link NOC:Symmetry and Group Theory (2021) Lecture 64 - Spectral Transition Probabilities - Part 2
Link NOC:Introductory Organic Chemistry - II Lecture 1 - Introduction - 1
Link NOC:Introductory Organic Chemistry - II Lecture 2 - Essentials of NMR Spectroscopy - Part 1
Link NOC:Introductory Organic Chemistry - II Lecture 3 - Essentials of NMR Spectroscopy - Part 2
Link NOC:Introductory Organic Chemistry - II Lecture 4 - Essentials of NMR Spectroscopy - Part 3
Link NOC:Introductory Organic Chemistry - II Lecture 5 - Electrophilic Aromatic Substitution - Part 1
Link NOC:Introductory Organic Chemistry - II Lecture 6 - Electrophilic Aromatic Substitution - Part 2
Link NOC:Introductory Organic Chemistry - II Lecture 7 - Electrophilic Aromatic Substitution - Part 3
Link NOC:Introductory Organic Chemistry - II Lecture 8 - Tutorial - 1
Link NOC:Introductory Organic Chemistry - II Lecture 9 - Introduction - 2
Link NOC:Introductory Organic Chemistry - II Lecture 10 - Electrophilic Aromatic Substitution in Phenols
Link NOC:Introductory Organic Chemistry - II Lecture 11 - EAS_Effect of Electron Donating group
Link NOC:Introductory Organic Chemistry - II Lecture 12 - EAS_Effect of Electron Withdrawing group
Link NOC:Introductory Organic Chemistry - II Lecture 13 - Nucleophilic aromatic substitution - Part 1
Link NOC:Introductory Organic Chemistry - II Lecture 14 - Nucleophilic aromatic substitution - Part 2
Link NOC:Introductory Organic Chemistry - II Lecture 15 - Special Topic_Hammond's Postulate
Link NOC:Introductory Organic Chemistry - II Lecture 16 - Tutorial-2 - Part 1
Link NOC:Introductory Organic Chemistry - II Lecture 17 - Tutorial-2 - Part 2
Link NOC:Introductory Organic Chemistry - II Lecture 18 - Essentials of IR Spectroscopy
Link NOC:Introductory Organic Chemistry - II Lecture 19 - Introduction - 3
Link NOC:Introductory Organic Chemistry - II Lecture 20 - Basics of Carbonyl Compounds
Link NOC:Introductory Organic Chemistry - II Lecture 21 - Addition Reactions on Carbonyl functional group
Link NOC:Introductory Organic Chemistry - II Lecture 22 - Addition Reactions on Carbonyl functional group
Link NOC:Introductory Organic Chemistry - II Lecture 23 - Nucleophilic Addition Reactions and its stereochemistry
Link NOC:Introductory Organic Chemistry - II Lecture 24 - Nucleophilic Addition Reactions and its Stereochemistry
Link NOC:Introductory Organic Chemistry - II Lecture 25 - Tutorial - 3
Link NOC:Introductory Organic Chemistry - II Lecture 26 - Introduction - 4
Link NOC:Introductory Organic Chemistry - II Lecture 27 - Carboxylic acid and its derivatives - Part 1
Link NOC:Introductory Organic Chemistry - II Lecture 28 - Carboxylic acid and its derivatives - Part 2
Link NOC:Introductory Organic Chemistry - II Lecture 29 - Reactions of Carboxylic acid and its derivatives
Link NOC:Introductory Organic Chemistry - II Lecture 30 - Alcohols, Ethers, and Epoxides
Link NOC:Introductory Organic Chemistry - II Lecture 31 - Tutorial - 4
Link NOC:Introductory Organic Chemistry - II Lecture 32 - Special Topic - E1CB reaction
Link NOC:Introductory Organic Chemistry - II Lecture 33 - Introduction - 5
Link NOC:Introductory Organic Chemistry - II Lecture 34 - Enols and Enolates_Intro
Link NOC:Introductory Organic Chemistry - II Lecture 35 - Enols and Enolates_Molecular Orbital Picture
Link NOC:Introductory Organic Chemistry - II Lecture 36 - Reactions of Enols and Enolates
Link NOC:Introductory Organic Chemistry - II Lecture 37 - Tutorial - 5A
Link NOC:Introductory Organic Chemistry - II Lecture 38 - Tutorial - 5B
Link NOC:Introductory Organic Chemistry - II Lecture 39 - Introduction - 6
Link NOC:Introductory Organic Chemistry - II Lecture 40 - Active methylene group
Link NOC:Introductory Organic Chemistry - II Lecture 41 - Aldol and related Reactions
Link NOC:Introductory Organic Chemistry - II Lecture 42 - Aldol Reactions: Specific enol equivalents - Part 1
Link NOC:Introductory Organic Chemistry - II Lecture 43 - Aldol Reactions: Specific enol equivalents - Part 2
Link NOC:Introductory Organic Chemistry - II Lecture 44 - Tutorial - 6
Link NOC:Introductory Organic Chemistry - II Lecture 45 - Introduction - 7
Link NOC:Introductory Organic Chemistry - II Lecture 46 - Conjugate Addition:1,2-addition and 1,4-addition
Link NOC:Introductory Organic Chemistry - II Lecture 47 - Conjugate Addition: Kinetic versus thermodynamic products
Link NOC:Introductory Organic Chemistry - II Lecture 48 - Conjugate Addition: Hard and Soft nucleophiles
Link NOC:Introductory Organic Chemistry - II Lecture 49 - Enol and Enolate alkylation
Link NOC:Introductory Organic Chemistry - II Lecture 50 - Regioselectivity of alkylation reactions
Link NOC:Introductory Organic Chemistry - II Lecture 51 - Acylation of enol/enolates and related Name Reactions
Link NOC:Introductory Organic Chemistry - II Lecture 52 - Tutorial-7: Felkin-Ahn Problems
Link NOC:Introductory Organic Chemistry - II Lecture 53 - Introduction - 8
Link NOC:Introductory Organic Chemistry - II Lecture 54 - Rearrangements - Part 1
Link NOC:Introductory Organic Chemistry - II Lecture 55 - Rearrangements - Part 2
Link NOC:Introductory Organic Chemistry - II Lecture 56 - Rearrangements - Part 3
Link NOC:Introductory Organic Chemistry - II Lecture 57 - Rearrangements - Part 4
Link NOC:Introductory Organic Chemistry - II Lecture 58 - Named Reactions - Part 1
Link NOC:Introductory Organic Chemistry - II Lecture 59 - Named Reactions - Part 2
Link NOC:Introductory Organic Chemistry - II Lecture 60 - Tutorial - 8
Link NOC:Introductory Organic Chemistry - II Lecture 61 - Conclusion
Link NOC:Elementary Electrochemistry Lecture 1 - Introduction to Elementary Electrochemistry
Link NOC:Elementary Electrochemistry Lecture 2 - The Laws of Electrochemistry and Electrolysis
Link NOC:Elementary Electrochemistry Lecture 3 - Applications of Faraday's Laws of Electrolysis
Link NOC:Elementary Electrochemistry Lecture 4 - Electrolytic Conduction: Arrhenius Theory of Electrolytic Dissociation
Link NOC:Elementary Electrochemistry Lecture 5 - Electrochemical/Galvanic Cell: Construction and Cell Reactions
Link NOC:Elementary Electrochemistry Lecture 6 - Numerical Problems on Faraday's Laws of Electrolysis
Link NOC:Elementary Electrochemistry Lecture 7 - Estimation of EMF of a Cell Using Potentiometer
Link NOC:Elementary Electrochemistry Lecture 8 - EMF of a Cell and Free Energy Change of a Reaction
Link NOC:Elementary Electrochemistry Lecture 9 - EMF of a Cell and Equilibrium Constant of a Reaction: The Nernst Equation
Link NOC:Elementary Electrochemistry Lecture 10 - Various Types of Electrodes (Glass,SHE,Calomel) in Electrochemistry
Link NOC:Elementary Electrochemistry Lecture 11 - Electrode Potential and Applications of Nernst Equation
Link NOC:Elementary Electrochemistry Lecture 12 - Numerical Problems: Nernst Equation, EMF of Half Cell Reactions
Link NOC:Elementary Electrochemistry Lecture 13 - Measurement of Cell EMF
Link NOC:Elementary Electrochemistry Lecture 14 - Electrochemical Cells: Liquid Junction Potential
Link NOC:Elementary Electrochemistry Lecture 15 - Electrolytic Solutions: Determination of Activity Coefficient
Link NOC:Elementary Electrochemistry Lecture 16 - Theory of Potentiometric Titrations
Link NOC:Elementary Electrochemistry Lecture 17 - Preparation of Primary Standard and Standardization of NaOH
Link NOC:Elementary Electrochemistry Lecture 18 - Potentiometric Titration of Strong Acid and Strong Base
Link NOC:Elementary Electrochemistry Lecture 19 - Potentiometric Titration of Weak Acid with Strong Base
Link NOC:Elementary Electrochemistry Lecture 20 - Potentiometric Titration of Dibasic Acid with Strong Base
Link NOC:Elementary Electrochemistry Lecture 21 - Experimental Calculation of Potentiometric Titrations
Link NOC:Elementary Electrochemistry Lecture 22 - Conductance and Conductivity of the Solution
Link NOC:Elementary Electrochemistry Lecture 23 - Experimental Methods to Determine Transport Number
Link NOC:Elementary Electrochemistry Lecture 24 - Experimental Method to Calculate Transport Number
Link NOC:Elementary Electrochemistry Lecture 25 - Electrolytic Solutions
Link NOC:Elementary Electrochemistry Lecture 26 - Conductance Measurement
Link NOC:Elementary Electrochemistry Lecture 27 - Variation of Conductance with Concentration
Link NOC:Elementary Electrochemistry Lecture 28 - Ionic Mobilities in terms of ion Conductivities
Link NOC:Elementary Electrochemistry Lecture 29 - Application of Conductance Measurement - Part 1
Link NOC:Elementary Electrochemistry Lecture 30 - Application of Conductance Measurement - Part 2
Link NOC:Elementary Electrochemistry Lecture 31 - Activities in Electrolytic Solutions
Link NOC:Elementary Electrochemistry Lecture 32 - Ionic Strength of an Electrolyte and its Importance
Link NOC:Elementary Electrochemistry Lecture 33 - Hydration of Ions and Their Ionic Mobility
Link NOC:Elementary Electrochemistry Lecture 34 - Solubility and Activity Product
Link NOC:Elementary Electrochemistry Lecture 35 - Applications of EMF and Conductance Measurement
Link NOC:Elementary Electrochemistry Lecture 36 - Dissociation Constant of Weak Acids
Link NOC:Elementary Electrochemistry Lecture 37 - Conductometric Titrations of Strong Acid with Strong Base
Link NOC:Elementary Electrochemistry Lecture 38 - Conductometric Titrations of Weak Acid with Strong Base
Link NOC:Elementary Electrochemistry Lecture 39 - Estimation of HCl and Ammonium Chloride in a Triple Mixture using NaOH
Link NOC:Elementary Electrochemistry Lecture 40 - Estimation of Total Chloride ion Concentration in Triple Mixture using Primary Standard AgNO3
Link NOC:Elementary Electrochemistry Lecture 41 - Validation of Ostwald Dilution Law using HCl
Link NOC:Elementary Electrochemistry Lecture 42 - Validation of Ostwald Dilution Law using Acetic Acid
Link NOC:Elementary Electrochemistry Lecture 43 - Calculation and Graph Plotting for Conductometric Experiments
Link NOC:Organic Chemistry-I (Tamil) Lecture 1 - Phenols Structure, Preparation, Properties and Reactions - Part 1
Link NOC:Organic Chemistry-I (Tamil) Lecture 2 - Phenols Structure, Preparation, Properties and Reactions - Part 2
Link NOC:Organic Chemistry-I (Tamil) Lecture 3 - Phenols Structure, Preparation, Properties and Reactions - Part 3
Link NOC:Organic Chemistry-I (Tamil) Lecture 4 - Phenols Structure, Preparation, Properties and Reactions - Part 4
Link NOC:Organic Chemistry-I (Tamil) Lecture 5 - Phenols Structure, Preparation, Properties and Reactions - Part 5
Link NOC:Organic Chemistry-I (Tamil) Lecture 6 - Phenols Structure, Preparation, Properties and Reactions - Part 6
Link NOC:Organic Chemistry-I (Tamil) Lecture 7 - Phenol Assignment I and II - Part 7
Link NOC:Organic Chemistry-I (Tamil) Lecture 8 - Carbonyl Compounds - Part 1
Link NOC:Organic Chemistry-I (Tamil) Lecture 9 - Carbonyl Compounds - Part 2 (Continued...)
Link NOC:Organic Chemistry-I (Tamil) Lecture 10 - Carbonyl Compounds - Part 3 (Continued...)
Link NOC:Organic Chemistry-I (Tamil) Lecture 11 - Carbonyl Compounds - Part 4 (Continued...)
Link NOC:Organic Chemistry-I (Tamil) Lecture 12 - Carbonyl Compounds Assignment I and II - Part 5
Link NOC:Organic Chemistry-I (Tamil) Lecture 13 - Carboxylic Acids - Part 1
Link NOC:Organic Chemistry-I (Tamil) Lecture 14 - Functional Derivatives - Part 2
Link NOC:Organic Chemistry-I (Tamil) Lecture 15 - Appendices I and II - Part 3
Link NOC:Organic Chemistry-I (Tamil) Lecture 16 - Carboxylic Acids - Assignment I and II - Part 4
Link NOC:Organic Chemistry-I (Tamil) Lecture 17 - Nitro Compounds
Link NOC:Organic Chemistry-I (Tamil) Lecture 18 - Amines Structure, Preparation and Properties - Part 1
Link NOC:Organic Chemistry-I (Tamil) Lecture 19 - Amines Appendices I to IV - Part 1 (Continued...)
Link NOC:Organic Chemistry-I (Tamil) Lecture 20 - Assignments I to II - Part 2
Link NOC:Organic Chemistry-I (Tamil) Lecture 21 - Green Chemistry Introduction - Part 1
Link NOC:Organic Chemistry-I (Tamil) Lecture 22 - Green Chemistry Terminologies and strategies in green chemistry - Part 2 (Continued...)
Link NOC:Organic Chemistry-I (Tamil) Lecture 23 - Approches to Less Polluting Reactions - Part 3
Link NOC:Organic Chemistry-I (Tamil) Lecture 24 - Biocatalysis - Part 4
Link NOC:Organic Chemistry-I (Tamil) Lecture 25 - Microwave mediated and photochemical reactions and conclusion - Part 5
Link NOC:Organic Chemistry-I (Tamil) Lecture 26 - Acknowledgement
Link Essentials in Immunolgy Lecture 1 - Introduction to the immune system
Link Essentials in Immunolgy Lecture 2 - Cells and Organs of the immune system - Part 1
Link Essentials in Immunolgy Lecture 3 - Cells and Organs of the immune system - Part 2
Link Essentials in Immunolgy Lecture 4 - Cells and Organs of the immune system - Part 3
Link Essentials in Immunolgy Lecture 5 - Innate immunity - Part 1
Link Essentials in Immunolgy Lecture 6 - Innate immunity - Part 2
Link Essentials in Immunolgy Lecture 7 - Development and differentiation of B cells - Part 1
Link Essentials in Immunolgy Lecture 8 - Signaling in B cells
Link Essentials in Immunolgy Lecture 9 - Organization of immunoglobulin genes and Mechanism of immunoglobulin gene rearrangement
Link Essentials in Immunolgy Lecture 10 - Generation of antibody diversity
Link Essentials in Immunolgy Lecture 11 - Immunoglobulin class switching Regulation of Immunoglobulin gene regulation
Link Essentials in Immunolgy Lecture 12 - Structures and functions of Immunoglobulin’s
Link Essentials in Immunolgy Lecture 13 - The three complement pathways
Link Essentials in Immunolgy Lecture 14 - Hypersensitivity type 1
Link Essentials in Immunolgy Lecture 15 - Hypersensitivity types 2, 3 ,4 and Autoimmunity
Link Essentials in Immunolgy Lecture 16 - Autoimmunity Autoimmuno-deficiencies f the B cells
Link Essentials in Immunolgy Lecture 17 - Autoimmuno-deficiencies f the B cells
Link Essentials in Immunolgy Lecture 18 - Cancer
Link Essentials in Immunolgy Lecture 19 - The major histocompatibility complex - Part 1
Link Essentials in Immunolgy Lecture 20 - The major histocompatibility complex - Part 2
Link Essentials in Immunolgy Lecture 21 - The major histocompatibility complex - Part 3
Link Essentials in Immunolgy Lecture 22 - The Major Histocompatibility Complex
Link Essentials in Immunolgy Lecture 23 - The Major Histocompatibility Complex: MHC class I pathway
Link Essentials in Immunolgy Lecture 24 - The Major Histocompatibility Complex: MHC class II pathway
Link Essentials in Immunolgy Lecture 25 - T cell receptors
Link Essentials in Immunolgy Lecture 26 - T cell Activation
Link Essentials in Immunolgy Lecture 27 - T cell Activation / Differentiation
Link Essentials in Immunolgy Lecture 28 - T cell synapse, motility and subsets
Link Essentials in Immunolgy Lecture 29 - T cell survival
Link Essentials in Immunolgy Lecture 30 - Cytokines - Part 1
Link Essentials in Immunolgy Lecture 31 - Cytokines - Part 2
Link Essentials in Immunolgy Lecture 32 - Autoimmunity
Link Essentials in Immunolgy Lecture 33 - Immunodeficiency
Link Essentials in Immunolgy Lecture 34 - Host response mechanisms during infectious diseases - Part 1
Link Essentials in Immunolgy Lecture 35 - Host response mechanisms during infectious diseases - Part 2
Link Essentials in Immunolgy Lecture 36 - Transplantation immunology
Link Essentials in Immunolgy Lecture 37 - Vaccines
Link Essentials in Immunolgy Lecture 38 - Antigens and Immunogens
Link Essentials in Immunolgy Lecture 39 - Synthetic vaccines
Link Essentials in Immunolgy Lecture 40 - Evolution of the immune system
Link Eukaryotic Gene Expression - basics and benefits Lecture 1 - Eukaryotic RNA polymerases and basal transcription factors
Link Eukaryotic Gene Expression - basics and benefits Lecture 2 - Diversity in core promoter elements
Link Eukaryotic Gene Expression - basics and benefits Lecture 3 - Diversity in general transcription factors
Link Eukaryotic Gene Expression - basics and benefits Lecture 4 - Proximal & Distal Promoter Elements, Enhancers and Silencers, Gene-specific Regulators
Link Eukaryotic Gene Expression - basics and benefits Lecture 5 - Transcription factors - DNA binding domains
Link Eukaryotic Gene Expression - basics and benefits Lecture 6 - Transcription factors - Transcription activation domain
Link Eukaryotic Gene Expression - basics and benefits Lecture 7 - Role of chromatin in eukaryotic gene regulation
Link Eukaryotic Gene Expression - basics and benefits Lecture 8 - Role of histones in eukaryotic gene regulation
Link Eukaryotic Gene Expression - basics and benefits Lecture 9 - Role of DNA methylation in eukaryotic gene regulation
Link Eukaryotic Gene Expression - basics and benefits Lecture 10 - Chromatin remodelling & gene regulation
Link Eukaryotic Gene Expression - basics and benefits Lecture 11 - mRNA processing - Role of RNA Pol II in mRNA capping and mRNA splicing
Link Eukaryotic Gene Expression - basics and benefits Lecture 12 - mRNA processing - Role of RNA Pol II in polyadenylation & mRNA editing
Link Eukaryotic Gene Expression - basics and benefits Lecture 13 - Regulation of RNA Pol I transcription
Link Eukaryotic Gene Expression - basics and benefits Lecture 14 - Regulation of RNA Pol III transcription
Link Eukaryotic Gene Expression - basics and benefits Lecture 15 - Signal Transduction Pathways - Introduction
Link Eukaryotic Gene Expression - basics and benefits Lecture 16 - Regulation of gene expression by cyclicAMP
Link Eukaryotic Gene Expression - basics and benefits Lecture 17 - Regulation of gene expression by second messengers other than cAMP
Link Eukaryotic Gene Expression - basics and benefits Lecture 18 - Regulation of gene expression by Protein Kinase C
Link Eukaryotic Gene Expression - basics and benefits Lecture 19 - Regulation of gene expression by Growth factors
Link Eukaryotic Gene Expression - basics and benefits Lecture 20 - Regulation of gene expression by cytokines
Link Eukaryotic Gene Expression - basics and benefits Lecture 21 - Regulation of gene expression by steroid hormones
Link Eukaryotic Gene Expression - basics and benefits Lecture 22 - Regulation of gene expression by type II nuclear receptors
Link Eukaryotic Gene Expression - basics and benefits Lecture 23 - Mechanism of transcriptional activation by nuclear receptors
Link Eukaryotic Gene Expression - basics and benefits Lecture 24 - Gene Regulation during Drosophila Development
Link Eukaryotic Gene Expression - basics and benefits Lecture 25 - Signal transduction pathways involved in embryonic development
Link Eukaryotic Gene Expression - basics and benefits Lecture 26 - Homeotic genes
Link Eukaryotic Gene Expression - basics and benefits Lecture 27 - Epigenetic regulation of gene expression during development
Link Eukaryotic Gene Expression - basics and benefits Lecture 28 - Embryonic stem cells and Transcription factor-mediated epigenetic reprogramming
Link Eukaryotic Gene Expression - basics and benefits Lecture 29 - Cloning and Expression vectors
Link Eukaryotic Gene Expression - basics and benefits Lecture 30 - Eukaryotic protein expression systems - I
Link Eukaryotic Gene Expression - basics and benefits Lecture 31 - Eukaryotic protein expression systems - II
Link Eukaryotic Gene Expression - basics and benefits Lecture 32 - Eukaryotic protein expression systems - III: Gene expression in mammalian cells using viral vectors
Link Eukaryotic Gene Expression - basics and benefits Lecture 33 - Human Gene Therapy
Link Eukaryotic Gene Expression - basics and benefits Lecture 34 - DNA vaccines
Link Eukaryotic Gene Expression - basics and benefits Lecture 35 - Transgenic animals
Link Eukaryotic Gene Expression - basics and benefits Lecture 36 - Transgenic plants
Link Eukaryotic Gene Expression - basics and benefits Lecture 37 - Knockout mic
Link Eukaryotic Gene Expression - basics and benefits Lecture 38 - Regulation of Eukaryotic Gene Expression by Small RNAs (RNA Interference, RNAi)
Link Eukaryotic Gene Expression - basics and benefits Lecture 39 - Genomics & Proteomics
Link Eukaryotic Gene Expression - basics and benefits Lecture 40 - Metabolic Engineering & Synthetic Biology
Link Introductory Quantum Chemistry Lecture 1 - Wave Paticle Duality
Link Introductory Quantum Chemistry Lecture 2 - Standing Waves
Link Introductory Quantum Chemistry Lecture 3 - Path Integrals and Schrodinger Equation
Link Introductory Quantum Chemistry Lecture 4 - Postulates - Part 1
Link Introductory Quantum Chemistry Lecture 5 - Postulates - Part 2
Link Introductory Quantum Chemistry Lecture 6 - Postulates - Part 3
Link Introductory Quantum Chemistry Lecture 7 - Separting Variables and Particle in a Box - Part 1
Link Introductory Quantum Chemistry Lecture 8 - Particle in a box - Part 2
Link Introductory Quantum Chemistry Lecture 9 - Particle in a box - Part 3
Link Introductory Quantum Chemistry Lecture 10 - Particle in a box-time dependent states-Expectations values and time dependent states
Link Introductory Quantum Chemistry Lecture 11 - Particle in a 3 dimensional box
Link Introductory Quantum Chemistry Lecture 12 - Particle in a well of finite depth
Link Introductory Quantum Chemistry Lecture 13 - Finite well, Delta and Step Functions
Link Introductory Quantum Chemistry Lecture 14 - Finite well (Continued...)
Link Introductory Quantum Chemistry Lecture 15 - Tunneling - Part 1
Link Introductory Quantum Chemistry Lecture 16 - Tunneling - Part 2
Link Introductory Quantum Chemistry Lecture 17 - Schrodinger equation for Harmonic Oscillator
Link Introductory Quantum Chemistry Lecture 18 - Harmonic Oscillator - The Series Solution
Link Introductory Quantum Chemistry Lecture 19 - Harmonic Oscillator - Generating function
Link Introductory Quantum Chemistry Lecture 20 - Harmonic Oscillator - Orthogonality of Eigenfunctions
Link Introductory Quantum Chemistry Lecture 21 - Hydrogen Atom: Separating centre of mass motion and integral motion
Link Introductory Quantum Chemistry Lecture 22 - Hydrogen Atom: Polar Co-ordinates
Link Introductory Quantum Chemistry Lecture 23 - Hydrogen atom continued : Separation of variables
Link Introductory Quantum Chemistry Lecture 24 - Hydrogen atom : Finding the functions Θ (θ) and Φ(φ)
Link Introductory Quantum Chemistry Lecture 25 - Finding R(r)
Link Introductory Quantum Chemistry Lecture 26 - Atomic Orbitals - Part 1
Link Introductory Quantum Chemistry Lecture 27 - Atomic Orbitals - Part 2
Link Introductory Quantum Chemistry Lecture 28 - Atomic Orbitals - Part 3
Link Introductory Quantum Chemistry Lecture 29 - Atomic Orbitals - Part 4 and Hermitian Operators
Link Introductory Quantum Chemistry Lecture 30 - Measurement, Uncertainty Principle
Link Introductory Quantum Chemistry Lecture 31 - Generalized Uncertainty Principle
Link Introductory Quantum Chemistry Lecture 32 - Generalized Uncertainty Principle (Continued...)
Link Introductory Quantum Chemistry Lecture 33 - Angular Momentum
Link Introductory Quantum Chemistry Lecture 34 - Angular Momentum (Continued...)
Link Introductory Quantum Chemistry Lecture 35 - Angular Momentum (Continued...) and Spin
Link Introductory Quantum Chemistry Lecture 36 - Pertubation Theory
Link Introductory Quantum Chemistry Lecture 37 - Pertubation Theory (Continued...)
Link Introductory Quantum Chemistry Lecture 38 - Variation Method - Introduction
Link Introductory Quantum Chemistry Lecture 39 - Variation Method - Proof and Illustration
Link Introductory Quantum Chemistry Lecture 40 - He atom wave function with spin included - Paulis principle
Link Introductory Quantum Chemistry Lecture 41 - Hydrogen Molecular ion - Linear variation method
Link Introductory Quantum Chemistry Lecture 42 - Hydrogen Molecular ion (Continued...)
Link Introductory Quantum Chemistry Lecture 43 - Hydrogen Molecular ion (Continued...)
Link Introductory Quantum Chemistry Lecture 44 - Molecuar Orbitals The Hydrogen Molecule
Link Introductory Quantum Chemistry Lecture 45 - MO and VB theory
Link Introductory Quantum Chemistry Lecture 46 - MO theory of diatoms
Link Introductory Quantum Chemistry Lecture 47 - Di-atomics (Continued...)
Link Introductory Quantum Chemistry Lecture 48 - Hybridization Huckel theory
Link Introductory Quantum Chemistry Lecture 49 - Huckel MO Theory (Continued...)
Link Introduction to Organometallic Chemistry Lecture 1 - Introduction to Organometallic chemistry
Link Introduction to Organometallic Chemistry Lecture 2 - Metal carbonyl complexes
Link Introduction to Organometallic Chemistry Lecture 3 - Metal carbonyls - Part II
Link Introduction to Organometallic Chemistry Lecture 4 - Ligand substitution reactions
Link Introduction to Organometallic Chemistry Lecture 5 - Substitutes for carbonyl ligands
Link Introduction to Organometallic Chemistry Lecture 6 - Carbene complexes
Link Introduction to Organometallic Chemistry Lecture 7 - Carbene complexes (Continued...)
Link Introduction to Organometallic Chemistry Lecture 8 - Non-Carbon Ancillary ligands
Link Introduction to Organometallic Chemistry Lecture 9 - Non-Carbon Ancillary ligands (Continued...)
Link Introduction to Organometallic Chemistry Lecture 10 - Metal alkyl complexes
Link Introduction to Organometallic Chemistry Lecture 11 - Ligand Insertion Reactions
Link Introduction to Organometallic Chemistry Lecture 12 - Metal alkene complexes
Link Introduction to Organometallic Chemistry Lecture 13 - Alkynes ?2 bonding
Link Introduction to Organometallic Chemistry Lecture 14 - Metal dihydrogen and hydrides
Link Introduction to Organometallic Chemistry Lecture 15 - Migratory Insertion reaction with alkynes
Link Introduction to Organometallic Chemistry Lecture 16 - ηm (m=4 dienes and m=2n,polyenes)
Link Introduction to Organometallic Chemistry Lecture 17 - Oxidative addition & Vaskas complex mechanism
Link Introduction to Organometallic Chemistry Lecture 18 - Reductive elimination
Link Introduction to Organometallic Chemistry Lecture 19 - Reductive Elimination mechanism
Link Introduction to Organometallic Chemistry Lecture 20 - Oxidative coupling with C-C bond formation
Link Introduction to Organometallic Chemistry Lecture 21 - Metathesis reactions
Link Introduction to Organometallic Chemistry Lecture 22 - Metal-allyls - ? 3 complexes-synthesis, bonding
Link Introduction to Organometallic Chemistry Lecture 23 - Metal-allyls - η 3 complexes-fluxionality, reactivity
Link Introduction to Organometallic Chemistry Lecture 24 - C-C single bond forming reactions
Link Introduction to Organometallic Chemistry Lecture 25 - ? 5 Cyclopentadienyl - complexes
Link Introduction to Organometallic Chemistry Lecture 26 - η6 arene Metal complexes
Link Introduction to Organometallic Chemistry Lecture 27 - Half sandwich complexes
Link Introduction to Organometallic Chemistry Lecture 28 - Reactivity changes in coordinated ligands
Link Introduction to Organometallic Chemistry Lecture 29 - The isolobal analogy
Link Introduction to Organometallic Chemistry Lecture 30 - Fluxional Properties of Organometallics
Link Introduction to Organometallic Chemistry Lecture 31 - Quantifying Steric and electronic factors
Link Introduction to Organometallic Chemistry Lecture 32 - Hydrogenation reactions
Link Introduction to Organometallic Chemistry Lecture 33 - Addition of HX to olefins
Link Introduction to Organometallic Chemistry Lecture 34 - Reactions with CO insertion
Link Introduction to Organometallic Chemistry Lecture 35 - Organometallics promoted C-X coupling
Link Introduction to Organometallic Chemistry Lecture 36 - Organometallic polymerization
Link Introduction to Organometallic Chemistry Lecture 37 - C-H activation
Link Introduction to Organometallic Chemistry Lecture 38 - Asymmetric Catalysis
Link Introduction to Organometallic Chemistry Lecture 39 - Medicinal applications of organometallic complexes
Link Introduction to Organometallic Chemistry Lecture 40 - Special Properties and Applications
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 1 - Introduction to NMR spectroscopy
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 2 - The alignment of nuclear spins in presence of magnetic field
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 3 - Introduction to rotating frame
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 4 - Free induction decay and Fourier transformation of FID
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 5 - NMR Hardware
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 6 - The concept of chemical shift
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 7 - Factors that affect chemical shifts
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 8 - Chemical shift referencing
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 9 - J-coupling
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 10 - Recap of basics
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 11 - Introduction to general one dimensional NMR experiment
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 12 - Practical aspects of recording a 1D NMR experiment - I
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 13 - Practical aspects of recording a 1D NMR experiment - II
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 14 - Practical aspects of recording a 1D NMR experiment - III
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 15 - NMR Data processing
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 16 - Basic aspects of 1D proton NMR analysis
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 17 - Analysis of an example 1D proton spectrum
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 18 - Analysis of 1D 1H NMR spectra of molecules - I
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 19 - Analysis of 1D 1H NMR spectra of molecules - II
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 20 - 1D 13C NMR
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 21 - Why do we need 2D NMR
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 22 - A qualitative explanation of how 2D NMR experiment works
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 23 - Principles of 2D COSY and Total correlation spectroscopy (2D TOCSY)
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 24 - 2D NOE-spectroscopy
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 25 - 2D NOESY and 2D ROESY
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 26 - What is heteronuclear correlation NMR spectroscopy
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 27 - Sensitivity enhancement of heternuclei via polarization transfer
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 28 - Heteronucler multiple quantum NMR spectroscopy (2D HMQC) and Heteronuclear single quantum NMR spectroscopy (2D HSQC)
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 29 - Practical aspects of recording and processing 2D HMQC or HSQC
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 30 - HMBC and its utility
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 31 - 2D HSQC TOCSY and its analysis with examples
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 32 - Structure determination of molecules by NMR
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 33 - Structure determination of peptides - I
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 34 - Structure determination of peptides - II
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 35 - Structure determination of peptides - III
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 36 - Chemical exchange
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 37 - Hydrogen or deuterium exchange
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 38 - Diffusion ordered spectroscopy DOSY I
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 39 - DOSY II
Link NOC:Principles and Applications of NMR Spectroscopy Lecture 40 - STD NMR for drug target interactions
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 1 - Introduction to NMR spectroscopy
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 2 - Energy levels in NMR spectroscopy: Quantum mechanical model and Vector model
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 3 - Observing the NMR signal
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 4 - Basic concepts in 1D NMR: Chemical shift and Spin-spin coupling
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 5 - Basic concepts in 1D NMR: Nuclear Spin Relaxation, 1H NMR and 13C NMR
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 6 - Basic concepts in 2D NMR spectroscopy
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 7 - Principles of 2D correlation spectroscopy COSY
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 8 - Principles of 2D Total correlation spectroscopy (TOCSY)
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 9 - 2D Nuclear Overhauser Effect Spectroscopy (NOESY)
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 10 - 2D NOESY and 2D ROESY
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 11 - Principles of 2D Heteronuclear NMR
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 12 - 2D Heteronuclear NMR: HSQC
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 13 - Heteronuclear multiple quantum coherence (HMQC) and single quantum coherence (HSQC) - Part I
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 14 - Heteronuclear multiple quantum coherence (HMQC) and single quantum coherence (HSQC) - Part II
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 15 - 2D HSQC-TOCSY
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 16 - 3D NMR Spectroscopy - Part I
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 17 - 3D NMR Spectroscopy - Part II
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 18 - 3D HNCA and 3D HNCO
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 19 - 3D HNCACB and 3D HN(CO)CACB
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 20 - Protein Backbone resonance assignment and side chain resonance assignment
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 21 - Basic concepts of protein structure
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 22 - Introduction to Structure Determination of Bio-Molecules by NMR
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 23 - Over-expression of proteins in Bacteria
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 24 - Isotope labeling of proteins for NMR studies - Part I
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 25 - Isotope labeling of proteins for NMR studies - Part II
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 26 - Isotope labeling of proteins for NMR studies - Part III
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 27 - Isotope labeling of proteins for NMR studies - Part IV
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 28 - Resonance assignments of Proteins - Part I
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 29 - Resonance assignments of Proteins - Part II
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 30 - Resonance assignments of Proteins - Part III
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 31 - Determination of protein secondary structure from NMR data: CSI method
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 32 - Determination of protein secondary structure from NMR data: J coupling based method
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 33 - Determination of protein tertiary structure from NMR data - Part I
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 34 - 3D NOESY HSQC
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 35 - Determination of protein tertiary structure from NMR data - Part II
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 36 - Understanding Protein ligand interaction by NMR : Chemical shift perturbation
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 37 - Understanding Protein ligand interaction by NMR : Chemical exchange
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 38 - Understanding Protein ligand interaction by NMR : T2 Filter
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 39 - Understanding Protein ligand interaction by NMR : STD NMR
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 40 - Understanding Protein ligand interaction by NMR : Transfer NOE NMR
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 41 - Understanding Protein ligand interaction by NMR : Diffusion ordered Spectroscopy (DOSY) - Part I
Link NOC:Multidimensional NMR Spectroscopy for Structural Studies of Biomolecules Lecture 42 - Understanding Protein ligand interaction by NMR : Diffusion ordered Spectroscopy (DOSY) - Part II
Link NOC:Symmetry and Structure in the Solid State Lecture 1 - Symmetry in 3D World
Link NOC:Symmetry and Structure in the Solid State Lecture 2 - Two Fold Axis Representation with the Help of Esher Diagrams
Link NOC:Symmetry and Structure in the Solid State Lecture 3 - Pure Rotation Axes
Link NOC:Symmetry and Structure in the Solid State Lecture 4 - Properties of Crystal
Link NOC:Symmetry and Structure in the Solid State Lecture 5 - Point Group Generation
Link NOC:Symmetry and Structure in the Solid State Lecture 6 - Combination ofSymmetry Elements
Link NOC:Symmetry and Structure in the Solid State Lecture 7 - Arrangement of Symmetry Equivalent Objects
Link NOC:Symmetry and Structure in the Solid State Lecture 8 - Introduction to Plane Lattices
Link NOC:Symmetry and Structure in the Solid State Lecture 9 - Bravais Lattices
Link NOC:Symmetry and Structure in the Solid State Lecture 10 - Details of Stereographic Projections
Link NOC:Symmetry and Structure in the Solid State Lecture 11 - Stereographic Projections (Continued)
Link NOC:Symmetry and Structure in the Solid State Lecture 12 - Point Group and Crystal Systems - 1
Link NOC:Symmetry and Structure in the Solid State Lecture 13 - Point Group and Crystal Systems - 2
Link NOC:Symmetry and Structure in the Solid State Lecture 14 - Point Groups to Space Groups
Link NOC:Symmetry and Structure in the Solid State Lecture 15 - Translation componentsin Monoclinic System
Link NOC:Symmetry and Structure in the Solid State Lecture 16 - Additional Symmetry Elements
Link NOC:Symmetry and Structure in the Solid State Lecture 17 - Additional Symmetry Elements (Continued...)
Link NOC:Symmetry and Structure in the Solid State Lecture 18 - Space Groups - 1
Link NOC:Symmetry and Structure in the Solid State Lecture 19 - Space Groups - 2
Link NOC:Symmetry and Structure in the Solid State Lecture 20 - Space Groups - 3
Link NOC:Symmetry and Structure in the Solid State Lecture 21 - Space Groups - 4
Link NOC:Symmetry and Structure in the Solid State Lecture 22 - Additional Information on Space Groups
Link NOC:Symmetry and Structure in the Solid State Lecture 23 - Details of Space Groups - 1
Link NOC:Symmetry and Structure in the Solid State Lecture 24 - Details of Space Groups - 2
Link NOC:Symmetry and Structure in the Solid State Lecture 25 - Details of Space Groups - 3
Link NOC:Symmetry and Structure in the Solid State Lecture 26 - Details of Space Groups - 4
Link NOC:Symmetry and Structure in the Solid State Lecture 27 - Crystal Structure of Calcium Carbonate
Link NOC:Symmetry and Structure in the Solid State Lecture 28 - Crystal Structure of Some Minerals
Link NOC:Symmetry and Structure in the Solid State Lecture 29 - Atoms in the Crystal: Positions and Relevant Properties
Link NOC:Symmetry and Structure in the Solid State Lecture 30 - Crystallographic Directions and Planes
Link NOC:Symmetry and Structure in the Solid State Lecture 31 - Interference of Waves
Link NOC:Symmetry and Structure in the Solid State Lecture 32 - X Ray Scattering ; optical Analogy
Link NOC:Symmetry and Structure in the Solid State Lecture 33 - X Ray Scattering ; Fourier transforms
Link NOC:Symmetry and Structure in the Solid State Lecture 34 - X Ray Scattering ; Deriving Laue Conditions from scattering theory
Link NOC:Symmetry and Structure in the Solid State Lecture 35 - X Ray Scattering ; Laue conditions to Bragg ‘s Law, Introduction to Reciprocal lattice
Link NOC:Symmetry and Structure in the Solid State Lecture 36 - Bragg's Law in Reciprocal Space - 1
Link NOC:Symmetry and Structure in the Solid State Lecture 37 - Bragg's Law in Reciprocal Space - 2
Link NOC:Symmetry and Structure in the Solid State Lecture 38 - Calculation of Intensities - 1
Link NOC:Symmetry and Structure in the Solid State Lecture 39 - Calculation of Intensities - 2
Link NOC:Symmetry and Structure in the Solid State Lecture 40 - Conversion from Direct to reciprocal space, the inverse relations
Link NOC:Symmetry and Structure in the Solid State Lecture 41 - Diffraction and Reciprocal Space (Continued...)
Link NOC:Symmetry and Structure in the Solid State Lecture 42 - Limits of Resolution
Link NOC:Symmetry and Structure in the Solid State Lecture 43 - Concept of Structure Factors
Link NOC:Symmetry and Structure in the Solid State Lecture 44 - Systematic Absences - 1
Link NOC:Symmetry and Structure in the Solid State Lecture 45 - Systematic Absences - 2
Link NOC:Symmetry and Structure in the Solid State Lecture 46 - Systematic Absences - 3
Link NOC:Symmetry and Structure in the Solid State Lecture 47 - Friedel's Law and Laue classes
Link NOC:Symmetry and Structure in the Solid State Lecture 48 - Experimental Aspects of Data Collection
Link NOC:Symmetry and Structure in the Solid State Lecture 49 - Structure Determination - 1
Link NOC:Symmetry and Structure in the Solid State Lecture 50 - Structure Determination - 2
Link NOC:Symmetry and Structure in the Solid State Lecture 51 - Data Reduction
Link NOC:Symmetry and Structure in the Solid State Lecture 52 - Fourier Syntheses
Link NOC:Symmetry and Structure in the Solid State Lecture 53 - Patterson Method - 1
Link NOC:Symmetry and Structure in the Solid State Lecture 54 - Patterson Method - 2
Link NOC:Symmetry and Structure in the Solid State Lecture 55 - Direct Method
Link NOC:Symmetry and Structure in the Solid State Lecture 56 - Powder Diffraction - 1
Link NOC:Symmetry and Structure in the Solid State Lecture 57 - Powder Diffraction - 2
Link NOC:Symmetry and Structure in the Solid State Lecture 58 - Powder Diffraction - 3
Link NOC:Symmetry and Structure in the Solid State Lecture 59 - Quantum Crystallography - 1
Link NOC:Symmetry and Structure in the Solid State Lecture 60 - Quantum Crystallography - 2
Link NOC:Symmetry and Structure in the Solid State Lecture 61 - Intermolecular Interactions
Link NOC:Ultrafast Optics and Spectroscopy Lecture 1
Link NOC:Ultrafast Optics and Spectroscopy Lecture 2
Link NOC:Ultrafast Optics and Spectroscopy Lecture 3
Link NOC:Ultrafast Optics and Spectroscopy Lecture 4
Link NOC:Ultrafast Optics and Spectroscopy Lecture 5
Link NOC:Ultrafast Optics and Spectroscopy Lecture 6
Link NOC:Ultrafast Optics and Spectroscopy Lecture 7
Link NOC:Ultrafast Optics and Spectroscopy Lecture 8 - Nonlinear Effects
Link NOC:Ultrafast Optics and Spectroscopy Lecture 9 - Nonlinear Effects (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 10 - Nonlinear Effects (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 11 - Nonlinear Effects (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 12 - Nonlinear Effects (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 13 - Nonlinear Effects (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 14 - Nonlinear Effects (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 15 - Dispersion Effects
Link NOC:Ultrafast Optics and Spectroscopy Lecture 16 - Nonlinear and Dispersion Effects (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 17 - Nonlinear and Dispersion Effects (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 18 - Transverse Electromagnetic Mode
Link NOC:Ultrafast Optics and Spectroscopy Lecture 19 - Transverse Electromagnetic Mode (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 20 - Construction of Ultrafast Laser
Link NOC:Ultrafast Optics and Spectroscopy Lecture 21 - Construction of Ultrafast Laser (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 22 - Construction of Ultrafast Laser (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 23 - Measurement of Ultrafast Pulse
Link NOC:Ultrafast Optics and Spectroscopy Lecture 24 - Measurement of Ultrafast Pulse (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 25 - Measurement Techniques in Ultrafast Spectroscopy
Link NOC:Ultrafast Optics and Spectroscopy Lecture 26 - Kinetic Model of Ultrafast Spectroscopy
Link NOC:Ultrafast Optics and Spectroscopy Lecture 27 - Kinetic Model of Ultrafast Spectroscopy (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 28 - Quantum Mechanical Model of Ultrafast Spectroscopy
Link NOC:Ultrafast Optics and Spectroscopy Lecture 29 - Ultrafast Physical Chemistry: Photophysics and Photochemistry
Link NOC:Ultrafast Optics and Spectroscopy Lecture 30 - Ultrafast Physical Chemistry: Solid State
Link NOC:Ultrafast Optics and Spectroscopy Lecture 31 - Ultrafast Physical Chemistry: Transition Metal Complexes and Biomolecules
Link NOC:Ultrafast Optics and Spectroscopy Lecture 32 - Maxwell’s Equations
Link NOC:Ultrafast Optics and Spectroscopy Lecture 33 - Maxwell’s Equations (Continued...)
Link NOC:Ultrafast Optics and Spectroscopy Lecture 34 - Ab Initio Molecular Dynamics - 1
Link NOC:Ultrafast Optics and Spectroscopy Lecture 35 - Ab Initio Molecular Dynamics - 2
Link NOC:Ultrafast Optics and Spectroscopy Lecture 36 - Ab Initio Molecular Dynamics - 3
Link NOC:Ultrafast Optics and Spectroscopy Lecture 37 - Ab Initio Molecular Dynamics - 4
Link NOC:Ultrafast Optics and Spectroscopy Lecture 38 - Attosecond Chemical Dynamics - 1
Link NOC:Ultrafast Optics and Spectroscopy Lecture 39 - Attosecond Chemical Dynamics - 2
Link NOC:Ultrafast Optics and Spectroscopy Lecture 40 - Attosecond Chemical Dynamics - 3
Link NOC:Ultrafast Optics and Spectroscopy Lecture 41 - Attosecond Chemical Dynamics - 4
Link NOC:Ultrafast Optics and Spectroscopy Lecture 42 - Femtochemistry of Nanocatalysis - 1
Link NOC:Ultrafast Optics and Spectroscopy Lecture 43 - Femtochemistry of Nanocatalysis - 2
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 1 - NMR an historical perspective and NMR active nuclei
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 2 - Spin Angular Momentum and Magnetic moment
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 3 - Interaction of Spins with the magnetic field
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 4 - Larmor Precession and Energy of interaction
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 5 - NMR detection and sensitivity
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 6 - Inducing Resonance and Bulk Magnetization
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 7 - Signal detection and Rotating Frame Concept
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 8 - Pulse phase and signal phase
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 9 - FID and Fourier Transformation
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 10 - Selection rules and transitions
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 11 - External and Internal interactions in NMR
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 12 - Chemical Shifts
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 13 - NMR Spectrum and chemical equivalence
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 14 - Conversion of frequency and ppm
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 15 - Field dependence and factors affecting chemical shift
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 16 - Factors contributing to chemical shifts - 1
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 17 - Factors contributing to chemical shifts - 2
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 18 - Scalar Couplings - 1
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 19 - Scalar Couplings - 2
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 20 - Energy levels of coupled spins
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 21 - Spin system classification and multiplicity
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 22 - Multiplicity pattern of coupled spins
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 23 - Active and passive coupling
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 24 - Coupling among equivalent spins - 1
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 25 - Coupling among equivalent spins - 2
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 26 - Coupling among non-equivalent spins
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 27 - Geminal and Vicinal couplings
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 28 - Spin system Nomenclature
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 29 - Isotope effect
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 30 - Analysis of Strongly coupled spin systems
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 31 - Eigen values of A2 and AMX spin systems
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 32 - Analysis of Three spin coupled systems
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 33 - Analysis of Proton NMR spectra - 1
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 34 - Analysis of Proton NMR spectra - 2
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 35 - Analysis of Proton NMR spectra - 3
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 36 - Basics of 13C-NMR
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 37 - Coupled and Decoupled 13C-Spectra
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 38 - Broadband decoupling in 13C-NMR
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 39 - Analysis of 13C spectra and DEPT
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 40 - Heteronuclear couplings and satellite analysis - 1
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 41 - Heteronuclear couplings and satellite analysis - 2
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 42 - Coupling among magnetic equivalent nuclei and isotope effect
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 43 - Analysis of spectra of other nuclei
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 44 - Spin Echoes
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 45 - Polarization transfer techniques
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 46 - INEPT and DEPT
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 47 - Decoupling and NOE
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 48 - NOE-2
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 49 - Introduction to 2D NMR
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 50 - Two-dimensional NMR
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 51 - Two dimensional NMR
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 52 - Two dimensional COSY
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 53 - COSY and examples
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 54 - Variants of COSY and TOCSY spectra
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 55 - Heteronuclear correlation and inverse detection
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 56 - Coupled and decoupled HSQC and HMBC
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 57 - NMR data acquisition - 1
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 58 - NMR data acquisition - 2
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 59 - Practical considerations of 1D NMR
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 60 - NMR Data processing
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 61 - NMR Data processing
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 62 - NMR Instrumentation - 1
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 63 - NMR Instrumentation - 2
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 64 - Relaxation processes - 1
Link NOC:One and two dimensional NMR Spectroscopy for Chemists Lecture 65 - Relaxation processes - 2
Link NOC:Time Dependent Quantum Chemistry Lecture 1 - Introduction to TDSE
Link NOC:Time Dependent Quantum Chemistry Lecture 2 - Solution to TDSE, Stationary and Non-stationary States
Link NOC:Time Dependent Quantum Chemistry Lecture 3 - Electron and Vibrational Superposition States
Link NOC:Time Dependent Quantum Chemistry Lecture 4 - Optical Analogy to Quantum Superposition
Link NOC:Time Dependent Quantum Chemistry Lecture 5 - Introdution to Python Programming
Link NOC:Time Dependent Quantum Chemistry Lecture 6 - Simple Computation with Python Programming
Link NOC:Time Dependent Quantum Chemistry Lecture 7 - Plotting Graph with Python Programming
Link NOC:Time Dependent Quantum Chemistry Lecture 8 - Meaning of Probability Density
Link NOC:Time Dependent Quantum Chemistry Lecture 9 - Time Evolution of Normalization Constant
Link NOC:Time Dependent Quantum Chemistry Lecture 10 - Expectation Value and its Time Evolution
Link NOC:Time Dependent Quantum Chemistry Lecture 11 - Equation of Continuity
Link NOC:Time Dependent Quantum Chemistry Lecture 12 - Bohmian Mechanics
Link NOC:Time Dependent Quantum Chemistry Lecture 13 - Bohmian Mechanics and Standard Interpretation
Link NOC:Time Dependent Quantum Chemistry Lecture 14 - Grid Representation of Wavefunction
Link NOC:Time Dependent Quantum Chemistry Lecture 15 - Normalizing the Discretized Wavefunction and Finding Expectation Value
Link NOC:Time Dependent Quantum Chemistry Lecture 16 - Plane Matter Wave and Wavepacket
Link NOC:Time Dependent Quantum Chemistry Lecture 17 - Wavepacket
Link NOC:Time Dependent Quantum Chemistry Lecture 18 - Stationary Gaussian Wavepacket
Link NOC:Time Dependent Quantum Chemistry Lecture 19 - Travelling Gaussian Wavepacket
Link NOC:Time Dependent Quantum Chemistry Lecture 20 - General Form of the Gaussian Wavepacket
Link NOC:Time Dependent Quantum Chemistry Lecture 21 - Fourer Transform of a wavefunction
Link NOC:Time Dependent Quantum Chemistry Lecture 22 - x-grid to k-grid
Link NOC:Time Dependent Quantum Chemistry Lecture 23 - Fourier Transform using fft
Link NOC:Time Dependent Quantum Chemistry Lecture 24 - Hilbert Space and Its Properties
Link NOC:Time Dependent Quantum Chemistry Lecture 25 - Basis Set Approach to Quantum Mechanics
Link NOC:Time Dependent Quantum Chemistry Lecture 26 - Matrix Algebra
Link NOC:Time Dependent Quantum Chemistry Lecture 27 - Eigenvalue and Eigenfunction
Link NOC:Time Dependent Quantum Chemistry Lecture 28 - Matrix Representation of Operators
Link NOC:Time Dependent Quantum Chemistry Lecture 29 - Matrix Representation of Hamiltonian Operator
Link NOC:Time Dependent Quantum Chemistry Lecture 30 - Python Tutorial 4 (Eigenvalue and Eigenfunction)
Link NOC:Time Dependent Quantum Chemistry Lecture 31 - Python Tutorial 4 (Eigenvalue and Eigenfunction)
Link NOC:Time Dependent Quantum Chemistry Lecture 32 - Time Evolution Operator
Link NOC:Time Dependent Quantum Chemistry Lecture 33 - Split Operator Metho
Link NOC:Time Dependent Quantum Chemistry Lecture 34 - Numerical Implementation of Split Operator Method
Link NOC:Time Dependent Quantum Chemistry Lecture 35 - Wavepacket Dynamics under zero interaction potential
Link NOC:Time Dependent Quantum Chemistry Lecture 36 - Wavepacket Dynamics under zero interaction potential (Continued...)
Link NOC:Time Dependent Quantum Chemistry Lecture 37 - Wavepacket Dynamics under linear interaction potential
Link NOC:Time Dependent Quantum Chemistry Lecture 38 - Quantum Adiabatic Theory
Link NOC:Time Dependent Quantum Chemistry Lecture 39 - Formal Derivation of Quantum Adiabat
Link NOC:Time Dependent Quantum Chemistry Lecture 40 - Geometric Phase and Dynamical Phase
Link NOC:Time Dependent Quantum Chemistry Lecture 41 - Nonradiative Transition - Part 1
Link NOC:Time Dependent Quantum Chemistry Lecture 42 - Nonradiative Transition - Part 2
Link NOC:Time Dependent Quantum Chemistry Lecture 43 - Nonradiative Transition
Link NOC:Time Dependent Quantum Chemistry Lecture 44 - Quantum Dissipative Dynamics
Link NOC:Time Dependent Quantum Chemistry Lecture 45 - Quantum Dissipative Dynamics
Link NOC:Time Dependent Quantum Chemistry Lecture 46 - Formal Derivation of Dissipative Quantum Dynamics
Link NOC:Time Dependent Quantum Chemistry Lecture 47 - Classical Description of Light
Link NOC:Time Dependent Quantum Chemistry Lecture 48 - Vector and Scalar Potential
Link NOC:Time Dependent Quantum Chemistry Lecture 49 - Vector and Scalar Potential
Link NOC:Time Dependent Quantum Chemistry Lecture 50 - Master Equation of Light
Link NOC:Time Dependent Quantum Chemistry Lecture 51 - Hamiltonian for Light-Atom Interaction
Link NOC:Time Dependent Quantum Chemistry Lecture 52 - Hamiltonian for Light-Atom Interaction
Link NOC:Time Dependent Quantum Chemistry Lecture 53 - Absorption and Stimulated Emission
Link NOC:Time Dependent Quantum Chemistry Lecture 54 - Absorption and Stimulated Emission
Link NOC:Time Dependent Quantum Chemistry Lecture 55 - Time Correlation Function
Link NOC:Time Dependent Quantum Chemistry Lecture 56 - Fourier Transform of Time Correlation Function
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 1 - Nuclear Spin
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 2 - NMR spin physics - I
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 3 - NMR spin physics - II
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 4 - Energy levels and allowed transitions
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 5 - Transitions in coupled spin systems
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 6 - Interaction parameters
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 7 - Chemical Shifts
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 8 - Shielding and deshielding, ppm and frequency scales
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 9 - Factors affecting the chemical shifts
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 10 - Scalar couplings
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 11 - Scalar couplings
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 12 - Coupling mechanism
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 13 - Splitting patterns
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 14 - Multiplicity patterns
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 15 - Analysis of multiplicity patterns
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 16 - Coupled spin system
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 17 - Nomenclature for coupled spins
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 18 - Energy levels of two and three coupled spins
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 19 - Analysis of 1H NMR spectra - I
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 20 - Analysis of 1H NMR spectra - II
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 21 - Analysis of 1H NMR spectra - III
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 22 - Coupling of 1H with other nuclei - I
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 23 - Coupling of 1H with other nuclei - II
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 24 - 13C-NMR - I
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 25 - 13C-NMR - II
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 26 - 13C-NMR - III
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 27 - 13C-NMR - IV
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 28 - Analysis of 19F spectra
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 29 - 31P NMR
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 30 - Analysis of spectra of Heteronuclei
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 31 - Heteronuclear spectral analysis
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 32 - Spin Echoes - I
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 33 - Spin Echoes - II
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 34 - Sensitivity enhancement
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 35 - Polarization transfer
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 36 - INEPT
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 37 - 2D NMR - I
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 38 - 2D NMR - II
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 39 - 2D-COSY - I
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 40 - 2D COSY - II
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 41 - Types of COSY spectra
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 42 - TOCSY
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 43 - HSQC - I
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 44 - HSQC - II
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 45 - me-HSQC
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 46 - HSQC and HMBC
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 47 - HMBC - II
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 48 - 2D INADEQUATE
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 49 - 2D-INADEQUATE and 2D J-Resolved
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 50 - Homo and Heteronuclear J-resolved
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 51 - Conceptual understanding of NOE
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 52 - Positive and negative NOE
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 53 - NOE and correlation times
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 54 - Complications in NOE, Steady state NOE
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 55 - ROESY and Tr NOE
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 56 - Combined utility of COSY, TOCSY, HSQC, NOESY
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 57 - Steady State NOE
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 58 - 1D NOE, 1D TOCSY
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 59 - 1D-TOCSY, PURESHIFT
Link NOC:One and Two Dimensional NMR Spectroscopy: Concepts and Spectral Analysis Lecture 60 - PURSHIFT NMR
Link BioChemistry I Lecture 1 - Amino Acids - I
Link BioChemistry I Lecture 2 - Amino Acids - II
Link BioChemistry I Lecture 3 - Protein Structure - I
Link BioChemistry I Lecture 4 - Protein structure - II
Link BioChemistry I Lecture 5 - Protein Structure - III
Link BioChemistry I Lecture 6 - Protein Structure - IV
Link BioChemistry I Lecture 7 - Enzymes - I
Link BioChemistry I Lecture 8 - Enzymes - II
Link BioChemistry I Lecture 9 - Enzymes - III
Link BioChemistry I Lecture 10 - Enzymes Mechanisms - I
Link BioChemistry I Lecture 11 - Enzymes Mechanisms - II
Link BioChemistry I Lecture 12 - Myoglobin and Hemoglobin
Link BioChemistry I Lecture 13 - Lipids and Membranes - I
Link BioChemistry I Lecture 14 - Lipids and Membranes - II
Link BioChemistry I Lecture 15 - Membrane Transport
Link BioChemistry I Lecture 16 - Carbohydrates - I
Link BioChemistry I Lecture 17 - Carbohydrates - II
Link BioChemistry I Lecture 18 - Vitamins and Coenzymes - I
Link BioChemistry I Lecture 19 - Vitamins and Coenzymes - II
Link BioChemistry I Lecture 20 - Nucleic Acids - I
Link BioChemistry I Lecture 21 - Nucleic Acids - II
Link BioChemistry I Lecture 22 - Nucleic Acids - III
Link BioChemistry I Lecture 23 - Bioenergetics - I
Link BioChemistry I Lecture 24 - Bioenergetics - II
Link BioChemistry I Lecture 25 - Metabolism - I
Link BioChemistry I Lecture 26 - Metabolism - II
Link BioChemistry I Lecture 27 - Metabolism - III
Link BioChemistry I Lecture 28 - Overview of the Course