Course : Organic Chemistry 1

Lecture Name Click to Open
W1M1 B Introduction to atomic orbital description
W1M1 C Common bonding pattern for C, N and O
W1M1 D Deconstruction of reactions
W1M1 E Arrow pushing
W1M2 A Geometric isomerism
W1M2 B CIP rule
W1M2 C Application of geometric isomerism
W1M2D1 cis trans Decalin
W1M2 D Geometric isomerism and healthy diet
W1M2 E hetero atom decalin
W1M3 A Basics of orbital
W1M3 Conformational analysis of alkanes, allylic strain
W1M3 D Dihedral angle analysis Klyne Prelog notation
W1M3 E Types of strain
W1M3 Introduction orbital, hybridisation, various projection
W1M3 Introduction to module 3
W1M4 A Introduction to module 4
W1M4 Conformations of cycloalkanes (3, 4 and 5 membered rings)
W1M4 Cyclohexane axial, equatorial bonds, ring flip
W1M4 Cyclohexane conformations, A-values
W1M4 Cyclohexane disubstituted, Prelog strain, fused rings
W1M4D6 Cyclopentane conformation
W1M4 E Conformational studies of Cyclopentane
W1M4 G A values in cyclohexyl derivatives
W1M4 I Comparison of various strains
W2M5 0 Symmetry and point group
W2M5 A Intro Module 5
W2M5 B Reflection
W2M5 C Examples of Reflection inversion
W2M5D1 rotation
W2M5D2 reflection
W2M5D3 inversion
W2M5D4 improper rotation
W2M5 D Point Groups
W2M5 n Symmetry and point group
W2M5 Reflection, Inversion, Improper rotation
W2M6 A ethane
W2M6 B example C2H6 EtOH
W2M6 C sym chirality
W2M6D1 point group analysis
W2M6D2 C2H6 EtOH
W2M7 0 Stereochemical conventions D L, cis trans, R S, exo endo, erythro threo
W2M7 A stereo notation upto Fisher
W2M7 B stereo notation upto R S
W2M7 C stereo notation upto P M
W2M7D1 erythro threo
W2M7D2 fischer saw horse
W2M7D3 alpha beta
W2M7D4 cis trans
W2M7D5 exo endo part 1
W2M7D10 RS Rotation of Bonds BN 1
W2M7 n Stereochemical conventions D L, cis trans, R S, exo endo, erythro threo
W3M8 A Re Si topicity
W3M8 B enantiomer diastereomer comparison
W3M8 C topicity and chiral reagents
W3M8D1 Re Si attack hydride
W3M8D2 Re Si attack Bromide
W3M8D3 Re Si carbonyl
W3M8D4 enantiotopic faces
W3M8D5 diastereotopic faces
W3M8D6 meso
W3M8 n Re Si faces convention with examples and Topicity homotopic, enantiotopic 1
W3M8 n Re Si faces convention with examples and Topicity homotopic, enantiotopic 2
W3M9 A determination of absolute configuration
W3M9 B polarised light
W3M9 C ORD CD
W3M10 0 Optical rotatory dispersion and circular Dichroism its application, Axia
W3M10 A Cotton octant
W3M10 B ORD CD application
W3M10D1 Axial halo ketone
W3M10D2 octant intro 1
W3M10D3 octant intro 2
W3M10D4 octant example
W4M11 0 Stereochemical reactions, stereospecific reactions
W4M11 A Stereochemical Reactions
W4M11 B bromination
W4M11 C epoxidtion
W4M11D1 Anti Addition Bromide part 1
W4M11D3 syn epoxidation
W4M11D4 Hydroboration Oxidation of Alkenes CIS Addition
W4M11 n Stereochemical reactions, stereospecific reactions
W4M12 0 Reactions involving stereo centres, Cram rule, Felkin Anh model, Prelog
W4M12 A reaction invovling stereo center
W4M12 B stereoselective reaction
W4M12D1 Reaction Involving Stereocenters
W4M12D2 Generation of 2nd chiral Centre
W4M12D3 Crams Rule Felkin Anh model
W5M12 n Reactions involving stereo centres, Cram rule, Felkin Anh model, Prelog
W5M13 0 Reactions of aromatic compounds_ Aromatic electrophilic substitution Nit
W5M13 A Aromatic Compounds
W5M13 B resonace stabilisation energy
W5M13 C Huckel Mo
W5M13D2 cyclobutadiene
W5M13D3 cyclopentadiene
W5M13D4 cycloheptatriene
W5M13 D ASE
W5M13 E Non Aromatic & Antiaromatic Compounds
W5M13 n Reactions of aromatic compounds_ Aromatic electrophilic substitution Nit
W5M14 0 Other Benzenoid derivatives_ Polycyclic aromatic hydrocarbon PAH, Clar r
W5M14 A Other Benzenoid Derivatives
W5M14-A Poly aromatic hydrocarbon 1
W5M14 B Genesis of Clar Rule
W5M14 C Polyacenes
W5M14 D 6 Membered Aromatic Heterocycles
W5M14 E Annulenes
W5M14 n Other Benzenoid derivatives_ Polycyclic aromatic hydrocarbon PAH, Clar r
W6M15 0 Opening Reactions of aromatic compounds Aromatic electrophilic substitut
W6M15 n Closing Reactions of aromatic compounds Aromatic electrophilic substitut
W6M15V1 Aromatic Electrophilic substitution, sigma and pi complex
W6M15V2 Aromatic Electrophilic substitution, Nitration, Halogenation
W6M15V3 Aromatic Electrophilic Substitution-Friedel-Crafts reactions
W6M15V4 Aromatic Electrophilic Substitution Substituent effect_orientation
W6M16 0 Opening Substitution reactions of aromatic systems ╤В╨Р╨г 1 SNAr substitution
W6M16V1 Aromatic nucleophilic substitution-basics
W6M16V2 Aromatic nucleophilic substitution-Addition-Elimination
W6M16V3 Aromatic nucleophilic substitution-Elimination-Addition
W6M17 0 Opening Substitution reactions of aromatic systems ╤В╨Р╨г 2 Ipso substitution
W6M17 n Closing Substitution reactions of aromatic systems ╤В╨Р╨г 2 Ipso substitution
W6M17V1- SNAr-ipso attack
W6M17V2 Aromatic nucleophilic substitution-Reactions of ipso intermediate, Cine
W6M17V3 Aromatic nucleophilic substitution-von Richter reaction
W7M18 0 Opening Reaction dynamics Free energy profile, Hammond╤В╨Р╨йs Postulate
W7M18 n Closing Reaction dynamics Free energy profile, Hammond╤В╨Р╨йs Postulate
W7M18V1 Reaction dynamics-basics
W7M18V2 Reaction dynamics-Hammond's Postulate
W7M18V3 Hammond postulate application
W7M19 0 Opening Linear Free energy relationship, Part 1 Hammett equation
W7M19 n Closing Linear Free energy relationship, Part 1 Hammett equation
W7M19V1 LFER- Hammett equation
W7M19V2 Substituent constant
W7M19V3 reaction constant
W8M20 0 Opening Linear Free energy relationship, Part 2 Modification of Hammett
W8M20 n Closing Linear Free energy relationship, Part 2 Modification of Hammett
W8M20V1 Modification of Hammett equation
W8M20V2 Modification of Hammett equation
W8M20V3 Taft equation
W8M21 0 Opening Curtin Hammett principle, Winstein Holness equation
W8M21D1 Winstein-Holness eqn application
W8M21 n Closing Curtin Hammett principle, Winstein Holness equation
W8M21V1 Introduction, various R-S in organic chemistry
W8M21V2 Curtin- Hammett principle
W8M21V3 different cases of Curtin-Hammett principle
W8M22 0 Opening Carbocation, Part 1 Generation, Structure and Geometry of Carboc
W8M22 n Closing Carbocation, Part 1 Generation, Structure and Geometry of Carboc
W8M22V1 Carbocation Introduction, generation
W8M22V2 Structure, geometry, stability of carbocations
W8M22V3 carbocation stabilising groups
W9M23 0 Opening Carbocation, Part 2 Stabilisation of carbocation, Reactions
W9M23 n Closing Carbocation, Part 2 Stabilisation of carbocation, Reactions
W9M23V1 Carbocation stabilisation and reactions
W9M23V1 Stability of carbocation-old
W9M23V2 Carbocation-orbital interaction, NGP
W9M23V3 Reactions of carbocations
W9M23V4 Carbocation in biosynthesis
W9M24 0 Opening Carbocation, Rearrangement 1 No Change in carbon skeleton, Chang
W9M24D1 DEMO WAGNER MEERWIN REARRANGEMENT
W9M24 n Closing Carbocation, Rearrangement 1 No Change in carbon skeleton, Chang
W9M24V1 Carbocation rearrangement-1,2- hydride shift, Allyl rearrangement
W9M24V2 Carbocation rearrangement-Neopentyl, Wagner-Meerwin shift
W9M24V3 Carbocation rearrangement-Pinacol-Pinacolone Neopentyl, Wolff rearrangem
W9M25 0 Opening Carbocation, Rearrangement 2 involvement of other electron defic
W9M25 n Closing Carbocation, Rearrangement 2 involvement of other electron defic
W9M25V1 Carbocation rearrangement-Stereochemistry of rearrangement
W9M25V2 Carbocation rearrangement-migration to atoms other than carbon
W9M25V3 Carbocation rearrangement-Anchimeric assistance_NGP
W10M26 0 Opening Carbanions 1 pKa and its significance
W10M26 n Closing Carbanions 1 pKa and its significance
W10M26V1 pKa and its significance
W10M26V2 Parameters that affect pKa-1
W10M26V3 Parameters that affect pKa-2
W10M27 0 Opening Carbanions 2 Hard and Soft Acid and Base principle
W10M27 n Closing Carbanions 2 Hard and Soft Acid and Base principle
W10M27V1 Application of pKa
W10M27V2 HSAB principle
W10M27V3 Klopman Salem equation, FMO model
W10M27V4 Application of HSAB principle
W10M28 0 Opening Carbanions 3 Structure, Formation, Stability, Reactivity
W10M28 n Closing Carbanions 3 Structure, Formation, Stability, Reactivity
W10M28V1 Carbanion- Structure, formation
W10M28V2 Carbanion formation
W10M28V3 base vs nucleophile
W10M28V4 carbanion stability
W11M29V1 Carbanion Reactions- Benzoin condensation, Benzilic acid rearrangement
W11M29V2 Wittig, Stevens, Favorskii rearrangement
W11M29V3 Umpolung-polarity inversion, Henry reaction
W11M30V1 Free radical_ Structure and stability
W11M30V2 Fenton, Bouveault-Blanc reaction, Kolbe electrolysis, structure and ste
W11M30V3 Free radical stability, substituents effect
W12M31V1 Free radical - Stability and reactions
W12M31V2 Free radical - Stability-factors that are important
W12M31V3 Free radical - reactivity, radical philicity
W12M32V1 Free radical reactions- atom abstraction, bromination
W12M32V2 Free radical reactions - radical addition, disproportionation
W12M32V3 Free radical cyclisation
W13M33V1- Free radical reactions- Fenton reaction, Kolbe electrolysis, Bouveault
W13M33V2 - Giese reaction, Hofmann-Loffler reaction, Barton decarboxylation
W13M33V3-Barton-McCombie reaction, Birch reduction, Sandmeyer reaction, Radical
W13M34V1-Carbenes, Types and properties
W13M34V2 - Carbene-Generation, stability
W13M34V3 - Carbene- reactions, rearrangements, Nitrenes
W14M35V1-Carbonyl addition-1
W14M35V2-Carbonyl addition 2
W14M35V3-Carbonyl addition 3
W14M36V1-Enols and enolate-1, haloform reaction, enolate formation
W14M36V2-Steric effect on enolate formation, regioselectivity, kinetic vs thermo
W14M36V3- Reactions of enolates, Alkylation of enolates, Michael addition
W14M37V1-Enamines, spectral evidences, formation of enamines
W14M37V2-Enamine formation, reactions of enamines
W14M37V3-Why enamines for alkylation, acylation of enamines
W15M38V1 Enol ethers, significance, formation of enol ethers
W15M38V2-Reactions of enol ethers, Mukaiyama Aldol reaction
W15M38V3 Choice of catalyst, Chemoselectivity, comparison of reactivity enolate
W15M39V1 Sharpless epoxidation, introduction, stereospecificity
W15M39V2-Sharpless epoxidation, stereospecificity, catalyst, catalytic cycle
W15M39V3 Click reaction, Cu Azide Alkyne Cycloaddition, mechanism of CuAAC
W15M40V1 Diels-Alder reaction, stereo and regioselectivity, rules governing DAR
W15M40V2 Examples of stereo and regio selectivity, exo-endo product
W15M40V3 FMO interactions, Intramolecular DAR, Heteroatom IMDA

Course : Organic Chemistry 1
Lecture : W1M2 B CIP rule


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