INTRODUCTORY CLASS?
Introducing the IIT-JAM Chemistry Course structure to the students
Syllabus Discussion
Time Table for the Month of October
MODULE 1 : SOLID STATE?
Crystals and crystal systems; X-rays; NaCl and KCl structures; close
packing; atomic and ionic radii; radius ratio rules; lattice energy; Born-Haber cycle;
isomorphism; heat capacity of solids.
PART IV : FACTORS AFFECTING LATTICE ENERGY1:27:13
PART V : QUIZ DISCUSSION1:25:11
PART I : CRYSTAL AND CRYSTAL SYSTEMS1:32:14
PART II : CLOSE PACKING IN SOLIDS,DENSITY OF SOLIDS1:30:40
PART III : MILLER INDICES,BRAGG’S LAW,LATTICE ENERGY1:30:40
MODULE 2 : PERIODIC TABLE?
Periodic classification of elements and periodicity in properties; general methods of isolation purification of elements.
PART I :PERIODIC TRENDS1:26:37
PART II : PERIODIC PROPERTIES1:19:23
MODULE 3 : CHEMICAL BONDING AND SHAPES OF COMPOUNDS:?
Types of bonding; VSEPR theory and shapes molecules; hybridization; dipole moment; ionic solids; structure of NaCl, CsCl, diamond and graphite; lace energy
Part II :VBT,CONCEPT OF HYBRIDISATION51:40
PART IV (a)-MOLECULAR ORBITAL THEORY AND RELATED CONCEPTS42:45
Part III:VSEPR33:47
PART IV (b)-MOLECULAR ORBITAL THEORY AND RELATED CONCEPTS45:05
PART I :INTRODUCTION AND TYPES OF CHEMICAL BONDING1:26:41
QUIZ
QUIZ WEEK-1
QUIZ WEEK-5
QUIZ WEEK-6
QUIZ WEEK-7
QUIZ WEEK-800:00:00
QUIZ WEEK-9
QUIZ WEEK-10
QUIZ WEEK-11
QUIZ WEEK-12
QUIZ WEEK-13
QUIZ WEEK-14
QUIZ WEEK-15
QUIZ WEEK-4
QUIZ WEEK-3
QUIZ WEEK-2
MODUEL 8 : s AND p BLOCK ELEMENTS?
General concepts on group relationships and gradation in properties; structure electron deficient compounds involving main group elements.
PART 1 :GENERAL CONCEPTS ON GROUP RELATIONSHIPS AND GRADATION IN PROPERTIES1:32:11
MODULE 4 : ATOMIC AND MOLECULAR STRUCTURE?
Fundamental particles; Bohr’s theory of hydrogen-like atom; wave-particle dual uncertainty principle; Schrödinger’s wave equation; quantum numbers; shapes of orbitals; Hund’s rule and Pauli’s exclusion principle; electronic configuration of simple homonuclear diatomic molecules.
PART I :FUNDAMENTAL PARTICLES; BOHR’S THEORY OF HYDROGEN-LIKE ATOM; WAVE-PARTICLE DUAL UNCERTAINTY PRINCIPLE1:23:20
PART II :SCHRÖDINGER’S WAVE EQUATION; QUANTUM NUMBERS; SHAPES OF ORBITALS;1:25:48
PART III :SHAPES OF ORBITALS; HUND’S RULE AND PAULI’S EXCLUSION PRINCIPLE; ELECTRONIC CONFIGURATION OF SIMPLE HOMONUCLEAR DIATOMIC MOLECULES1:27:23
MODULE 5 : CHEMICAL KINETICS?
Reactions of various order; Arrhenius equation; collision theory; transition state theory; chain reactions – normal and branched; enzyme kinetics; photochemical processes; catalysis
PART I :INTRODUCTION,REACTIONS OF VARIOUS ORDER1:22:49
PART II : HALF LIFE, ORDER OF THE REACTION1:31:46
MODULE 6 : CHEMICAL ADSORPTION?
Gibbs adsorption equation; adsorption isotherm; types of adsorption; surface area of adsorbents; surface fi on liquids
PART I : INTRODUCTION,GIBBS ADSORPTION EQUATION; TYPES OF ADSORPTION; SURFACE AREA OF ADSORBENTS1:22:32
PART II : TYPES OF ADSORPTION; SURFACE AREA OF ADSORBENTS; SURFACE ON LIQUIDS1:29:59
MODULE 7 : BASIC ORGANIC CHEMISTRY?
Electronic effects (resonance, inductive, hyper conjugation) steric effects and its applications (acid/base property); optical isomerism in compounds with and without any stereocenters (allenes, biphenyls); conformation of acyclic systems (substituted ethane/n-propane/nbutane) and cyclic systems (mono and di-substituted cyclohexanes). Organic
PART I : AROMATICITY1:34:35
PART 2 :INDUCTIVE EFFECT, ELECTROMERIC EFFECT, RESONANCE EFFECT1:21:33
PART 3 : TYPES OF REACTIONS1:25:00
MODULE 9 : HETEROCYCLIC CHEMISTRY?
MONOCYCLIC, BICYCLIC AND TRICYCLIC AROMATIC HYDROCARBONS, AND MONOCYCLIC COMPOUNDS WITH ONE HETERO ATOM: SYNTHESIS, REACTIVITY AND PROPERTIES.
PART I : SYNTHESIS, ELECTRTOPHILLIC REACTIONS AND COMPARISION OF BASIC NATURE OF MONOCYCLIC COMPOUNDS1:31:24
MODULE 10: CHEMISTRY OF NATURAL PRODUCTS?
CHEMISTRY OF ALKALOIDS, STEROIDS, TERPENES, CARBOHYDRATES, AMINO ACIDS, PEPTIDES AND NUCLEIC ACIDS
PART I : CARBOHYDRATES,TARPENES1:47:54
PART 2 :ALKALOIDS, STEROIDS,AMINO ACIDS, PEPTIDES AND NUCLEIC ACIDS1:29:04
MODULE 11 :ELECTROCHEMISTRY?
Conductance and its applications; transport number; galvanic cells; EMF and free energy; concentration cells with and without transport; polarography; concentration cells with and without transport; Debey-Huckel-Onsagar theory of strong electrolytes.
PART I : INTRODUCTION TO ELECTROCHEMISTRY1:28:56
PART II : TRANSPORT NUMBER,ELECTROCHEMICAL CELLS,IONIC ACTIVITY1:00:13
PART III : NERNST EQUATION,CONCENTRATION CELL1:00:13
MODULE 12 :CHEMICAL THERMODYNAMICS?
Reversible and irreversible processes; first law and its application to ideal and non ideal gas thermochemistry; second law; entropy and free energy; criteria for spontaneity.
PART II : ENTROPY AND FREE ENERGY1:20:10
PART I : INTRODUCTION TO CHEMICAL THERMODYNAMICS1:21:43
PART IV : Q & A DISCUSSION1:29:12
PART III :LAWS OF THERMODYNAMICS1:24:26
MODULE 13 : ORGANIC REACTION MECHANISM AND SYNTHETIC APPLICATIONS?
Chemistry of reactive intermediates (carbocations, carbanion free radicals, carbenes, nitrenes, benzynes etc…); Hofmann-Curtius-Lossen rearrangement, Wolff rearrangement, Simmons Smith reaction, Reimer-Tiemann reaction, Michael reaction, Darzens reaction, Wittig reaction and McMurry reaction Pinacol-pinacolone, Favorskii, benzilic acid rearrangement, dienone-phenol rearrangement, Baeyer-Villeger reaction oxidation and reduction reactions in organic chemistry; organometallic reagents in organic synthesis (Grignard organolithium and organocopper); Diels-Alder, electrocyclic and sigma tropic reactions; functional group inter-conversion and structural proble
PART I : CHEMISTRY OF REACTIVE INTERMEDIATES -CARBOCATIONS, CARBANION FREE RADICALS, CARBENES, NITRENES, BENZYNES1:17:52
MODULE 14:COORDINATION CHEMISTRY?
coordination complexes: structure, isomerism, reaction mechanism and electronic spectra; VB, MO and Crystal Field theoretical approaches
for structure, color and magnetic properties of metal complexes; organometallic compounds having liga with back bonding capabilities such as metal carbonyls, carbenes, nitrosyls and metallocenes; homogenous catalysis
PART I-INTRODUCTION TO COORDINATION CHEMISTRY,NOMENCLATURE1:47:48
PART II : WERNERS THEORY,VBT AND CFT1:29:55
PART III- CRSTAL FIELD THEORY,COLOR AND MAGNETIC PROPERTIES1:32:49
MODULE 15 : CHEMICAL AND PHASE EQULIBRIA?
Law of mass action; Kp, Kc, Kx and Kn; effect of temperature on K; ionic equilibria solutions; pH and buffer solutions; hydrolysis; solubility product; phase equilibria–phase rule and its application to one component and two-component systems; colligative properties
PART I : CHEMICAL EQUILIBRIA1:29:24
PART II : IONIC AND PHASE EQUILIBRIA1:40:09
MODULE 16 : TRANSITION METALS?
Characteristics of 3d elements; oxide, hydroxide and salts of first row metals
PART I : d-BLOCK ELEMENTS1:21:04
PART II : f-BLOCK ELEMENTS1:23:11
MODULE 17 : INSTRUMENTAL METHODS OF ANALYSIS?
Basic principles; instrumentations and simple applications of conductometry, potentiometry and UV-vis spectrophotometry; analysis of water, air and soil samples.
PART I :BASIC PRINCIPLES OF INSTRUMENTAL ANALYSIS1:37:35
MODULE 18 : ANALYTICAL CHEMISTRY?
Principles of qualitative and quantitative analysis; acid-base, oxidation-reduction complexometric titrations using EDTA; precipitation reactions; use of indicators; use of organic reagents in inorganic analysis; radioactivity; nuclear reactions; applications of isotopes.
PART II : Q & A DISCUSSION ON NUCLEAR CHEMISTRY1:22:32
PART I :NUCLEAR CHEMISTRY2:03:32
MODULE 19 : SPECTROSCOPY?
Beer-Lambert law; fundamental concepts of rotational, vibrational, electronic and magnetic resonance spectroscopy.
PART II : Q & A DISCUSSION41:03
PART I : ROTATION ,VIBRATIONAL SPECTROSCOPY1:47:48
PART III : Q & A DISCUSSION13:24
MODULE 20 : STEREOCHEMISTRY?
optical isomerism in compounds with and without any stereocenters (allenes, biphenyls); conformation of acyclic systems (substituted ethane/n-propane/nbutane) and cyclic systems (mono and di-substituted cyclohexanes).
PART I :GROUP THEORY AND STEREOCHEMISTRY1:25:21
PART II : OPTICAL ACTIVITY1:23:36
MODULE 21 : ORGANIC REACTION MECHANISMS?
Hofmann-Curtius-Lossen rearrangement, Wolff rearrangement, Simmons Smith reaction, Reimer-Tiemann reaction, Michael reaction, Darzens reaction, Wittig reaction and McMurry reaction Pinacol-pinacolone, Favorskii, benzilic acid rearrangement, dienone-phenol rearrangement, Baeyer-Villeger reaction oxidation and reduction reactions in organic chemistry
PART 1 : HOFMANN,CURTIUS,LOSSEN,WOLFF PINACOL-PINACOLONE REARRANGEMENT, SIMMONS SMITH, REIMER-TIEMANN , MICHAEL, DARZENS, WITTIG AND MCMURRY REACTION PINACOL-PINACOLONE1:15:21
PART II : FAVORSKII, BENZILIC ACID REARRANGEMENT, DIENONE-PHENOL REARRANGEMENT, BAEYER-VILLEGER REACTION OXIDATION AND REDUCTION REACTIONS IN ORGANIC CHEMISTRY;1:13:09
CRASH COURSE
GENERAL PHYSICAL AND INORGANIC CHEMISTRY1:39:06
GENERAL PHYSICAL AND ANALYTICAL CHEMISTRY1:23:51
GENERAL ORGANIC CHEMISTRY1:28:55
GENERAL ORGANIC AND INORGANIC CHEMISTRY1:00:04
