JAM ACHIEVER COURSE - Chemistry (2019)

Module: IIT - JAM THEORETICAL COURSE - Chemistry (CY)

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• Subject: CHEMISTRY (CY)
  • Section : Units
    • Unit 1: BASIC MATHEMATICAL CONCEPTS

      Lecture 1: Function

      • 1

      Lecture 2: Maxima and Minima

      • 1

      Lecture 3: Integrals

      • 1

      Lecture 4: Ordinary Differential Equations

      • 1

      Lecture 5: Vectors

      • 1

      Lecture 6: Matrices

      • 1

      Lecture 7: Determinants

      • 1

      Lecture 8: Elementary Statistics

      • 1

      Lecture 9: Probability Theory

      • 1
    • Unit 2: ATOMIC AND MOLECULAR STRUCTURE

      Lecture 1: Fundamental Particles

      • 1

      Lecture 2: Bohr’s Theory of Hydrogen-Like Atom

      • 1

      Lecture 3: Wave-Particle Duality

      • 1

      Lecture 4: Heisenberg Uncertainty Principle

      • 1

      Lecture 5: Schrodinger’s Wave Equation

      • 1

      Lecture 6: Quantum Numbers

      • 1

      Lecture 7: Pauli’s Exclusion Principle

      • 1

      Lecture 8: Hund’s Maximum Multiplicity Rule

      • 1

      Lecture 9: Electronic Configuration of Simple Homonuclear Diatomic Molecules

      • 1
    • Unit 3: THEORY OF GASES AND SOLID STATE

      Lecture 1: Theory of Gases

      • 1

      Lecture 2: Equation of State of Ideal and Non-Ideal Gases

      • 1

      Lecture 3: Maxwell-Boltzmann Distribution Law

      • 1

      Lecture 4: Equipartition of Energy

      • 1

      Lecture 5: Solid State

      • 1

      Lecture 6: Close Packing in Crystals

      • 1

      Lecture 7: X-Rays

      • 1

      Lecture 8: Lattice Energy

      • 1
    • Unit 4: CHEMICAL THERMODYNAMICS AND PHASE EQUILIBRIA

      Lecture 1: Chemical Thermodynamics

      • 1

      Lecture 2: The First Law of Thermodynamics

      • 1

      Lecture 3: Thermochemistry

      • 1

      Lecture 4: The Second Law of Thermodynamics

      • 1

      Lecture 5: Chemical Equilibrium

      • 1

      Lecture 6: Ionic Equilibrium

      • 1

      Lecture 7: Phase Equilibria and Phase Diagrams

      • 1
    • Unit 5: ELECTROCHEMISTRY

      Lecture 1: Conductance and Its Applications

      • 1

      Lecture 2: Transport Number

      • 1

      Lecture 3: Debey-Huckel-Onsagar Theory of Strong Electrolytes

      • 1

      Lecture 4: Galvanic Cell

      • 1

      Lecture 5: Electrode Potential and Free Energy

      • 1

      Lecture 6: Concentration Cells with and without Transport

      • 1

      Lecture 7: Polarography

      • 1
    • Unit 6: CHEMICAL KINETICS AND ADSORPTION

      Lecture 1: Rates of Reactions

      • 1

      Lecture 2: Arrhenius Equation

      • 1

      Lecture 3: The Collision Theory of Reaction Rates

      • 1

      Lecture 4: Enzyme Kinetics

      • 1

      Lecture 5: Catalysis

      • 1

      Lecture 6: Chain Reactions

      • 1

      Lecture 7: Photochemical Processes

      • 1

      Lecture 8: Gibbs Adsorption Equation

      • 1

      Lecture 9: Adsorption Isotherms

      • 1

      Lecture 10: Types of Adsorption

      • 1

      Lecture 11: Surface Area of Adsorbents

      • 1

      Lecture 12: Surface Firms on Liquids

      • 1

      Lecture 13: Beer’s Law

      • 1

      Lecture 14: Rotational and Vibrational Spectroscopy

      • 1

      Lecture 15: Electronic Spectroscopy

      • 1

      Lecture 16: Magnetic Resonance Spectroscopy

      • 1
    • Unit 7: BASIC CONCEPTS IN ORGANIC CHEMISTRY AND STEREOCHEMISTRY

      Lecture 1: Electronic Effects

      • 1

      Lecture 2: Steric Effects

      • 1

      Lecture 3: Stereoisomerism

      • 1

      Lecture 4: Conformations of Acyclic System

      • 1

      Lecture 5: Conformations of Cyclohexanes

      • 1
    • Unit 8: ORGANIC REACTION MECHANISM AND SYNTHETIC APPLICATIONS

      Lecture 1: Organic Reaction Mechanism

      • 1

      Lecture 2: Chemistry Reactive Intermediates (Carbine, Nitrene, Benzyne)

      • 1

      Lecture 3: Name Reactions and Reagents

      • 1

      Lecture 4: Organometallic Reagents

      • 1

      Lecture 5: Oxidizing Agents

      • 1

      Lecture 6: Reducing Agents

      • 1
    • Unit 9: QUALITATIVE AND HETEROCYCLIC CHEMISTRY

      Lecture 1: Functional Group Interconversions

      • 1

      Lecture 2: Chemical Tests for Functional Groups

      • 1

      Lecture 3: Proton Nuclear Magnetic Resonance Spectroscopy (H-NMR)

      • 1

      Lecture 4: Alkaloids

      • 1

      Lecture 5: Steroids

      • 1

      Lecture 6: Terpenes

      • 1

      Lecture 7: Biomolecules

      • 1

      Lecture 8: Classification and Nomenclature of Heterocyclic Compounds

      • 1

      Lecture 9: Aromatic Chemistry

      • 1
    • Unit 10: PERIODIC TABLE AND CHEMICAL BONDING

      Lecture 1: Basics of Periodic Table

      • 1

      Lecture 2: General Principles and Processes of Isolation of Elements

      • 1

      Lecture 3: Chemical Bonding and Shapes of Compounds

      • 1

      Lecture 4: Ionic Solids

      • 1

      Lecture 5: Structure of Some Solids

      • 1

      Lecture 6: Hybridization

      • 1

      Lecture 7: VSEPR Theory and Shapes of Molecules

      • 1
    • Unit 11: s and p - BLOCKS

      Lecture 1: Chemistry of s and p-Block Elements including Noble Gases

      • 1

      Lecture 2: p-Block Elements Properties Application of Main Group Elements

      • 1
    • Unit 12: TRANSITION METAL (d - BLOCK)

      Lecture 1: Transition Metal Chemistry

      • 1

      Lecture 2: Oxidation States

      • 1

      Lecture 3: Colors of Transition Metal Complexes

      • 1

      Lecture 4: Coordination Compounds

      • 1

      Lecture 5: Metal Oxidation State

      • 1

      Lecture 6: Valence Bond Approach

      • 1

      Lecture 7: Crystal Field Approach

      • 1

      Lecture 8: Organometallic Compounds

      • 1

      Lecture 9: Nitrosyls

      • 1

      Lecture 10: Metallocene

      • 1

      Lecture 11: Metal Carbonyl Compounds

      • 1

      Lecture 12: Electronic (Absorption) Spectra

      • 1

      Lecture 13: Homogeneous Catalysis

      • 1
    • Unit 13: Bio-Inorganic Chemistry

      Lecture 1: Metal Ions in The Biological System

      • 1

      Lecture 2: The Roles of Metal Ions

      • 1

      Lecture 3: Oxygen binding to Hb and Mb

      • 1

      Lecture 4: Redox Reaction

      • 1

      Lecture 5: Carbonic Anhydrase

      • 1
    • Unit 14: INSTRUMENTAL METHODS OF ANALYSIS

      Lecture 1: Basic Principles of Instrumentation

      • 1

      Lecture 2: Instrumentation and Applications of Conductometry

      • 1

      Lecture 3: Instrumentation and Applications of Potentiometry

      • 1

      Lecture 4: Ultravioletvisible (UVvis) Spectroscopy

      • 1

      Lecture 5: Analysis of Water, Air and Soil Sample

      • 1
    • Unit 15: ANALYTICAL CHEMISTRY

      Lecture 1: Principles of Qualitative and Quantitative Analysis

      • 1

      Lecture 2: Redox Reactions

      • 1

      Lecture 3: Chemistry and Properties of EDTA

      • 1

      Lecture 4: Precipitation Reactions

      • 1

      Lecture 5: Organic Analytical Reagents for The Determination

      • 1

      Lecture 6: Nuclear Chemistry

      • 1

      Lecture 7: Applications of Radioactive Isotopes

      • 1

This Package Also Includes

3

Practice Tests

Practice 1: Unit Solved Papers (1 - 15) Chemistry - CY

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Practice 2: Volume Solved Papers (1 - 5) Chemistry - CY

Practice 3: Previous Year Solved Papers (2015, 2016, 2017, 2018) Chemistry - CY

12

Mock Tests

Mock 1: Model Solved Paper - 1 (Chemistry - CY)

Start Demo

Mock 2: Model Solved Paper - 2 (Chemistry - CY)

Mock 3: Model Solved Paper - 3 (Chemistry - CY)

Mock 4: Model Solved Paper - 4 (Chemistry - CY)

Mock 5: Model Solved Paper - 5 (Chemistry - CY)

Mock 6: Model Solved Paper - 6 (Chemistry - CY)

Mock 7: Model Solved Paper - 7 (Chemistry - CY)

Mock 8: Model Solved Paper - 8 (Chemistry - CY)

Mock 9: Model Solved Paper - 9 (Chemistry - CY)

Mock 10: Model Solved Paper - 10 (Chemistry - CY)

Mock 11: Model Solved Paper - 11 (Chemistry - CY)

Mock 12: Model Solved Paper - 12 (Chemistry - CY)