MHCET_CHEMISTRY

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Physical Chemistry:
This branch of chemistry focuses on the fundamental principles that govern the behavior of matter. Topics often include:
Atomic Structure and Chemical Bonding
Thermodynamics and Thermochemistry
Chemical Equilibrium
Chemical Kinetics
Electrochemistry
Surface Chemistry
Organic Chemistry:
Organic chemistry deals with the study of compounds containing carbon. It's important to understand the structure, properties, and reactions of organic molecules. Key topics include:
Nomenclature and Isomerism
General Organic Chemistry (functional groups, reactions, and mechanisms)
Hydrocarbons, Alcohols, Phenols, and Ethers
Aldehydes and Ketones
Carboxylic Acids and their Derivatives
Amines and Biomolecules
Inorganic Chemistry:
Inorganic chemistry covers the properties and behaviors of inorganic compounds, which are typically not based on carbon. Important topics include:
Classification of Elements and Periodicity in Properties
Chemical Bonding and Coordination Compounds
p-Block, d-Block, and f-Block Elements
Metallurgy and Qualitative Analysis
Environmental Chemistry

Course Curriculum

1.Some Basic Concepts of Chemistry
These foundational concepts include atomic structure, bonding, reactions, states of matter, solutions, acids and bases, and serve as the cornerstone for further exploration in the field of chemistry.

Importance Of Chemistry

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Nature Of Matter

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Laws Of Chemical Combinations

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Law Of Conservation Of Mass

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Law Of Definite Proportions

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Law Of Multiple Proportions

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Gay Lussacs Law Of Gaseous Volumes

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Avogadro Law

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Daltons Atomic Theory

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Atomic And Molecular Masses

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Atomic Mass, Average Atomic Mass

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Mole Concept And Molar Masses

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Some Basic Concepts Of Chemistry

2.Introduction to Analytical Chemistry
Analytical Chemistry is a branch of chemistry that focuses on the identification and quantification of substances and the analysis of their chemical composition. It plays a crucial role in various scientific fields and industries, including pharmaceuticals, environmental monitoring, forensics, food and beverage production, and more. The primary goal of analytical chemistry is to determine the composition of a sample, understand its properties, and provide accurate and reliable data for decision-making and problem-solving.

Introduction Introduction to Analytical Chemistry

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The International System Of Units (SI)

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Mass, Weight,density and temperature

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Introduction

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Precision and Accuracy

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Significant Figures

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Dimensional Analysis

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Percentage Composition

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Empirical Formula For Molecular Formula

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Introduction

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Limiting Reagent

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Reactions In Solutions.

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Mass percent ,Mole Fraction,Molarity

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Introduction to Analytical Chemistry

3. Structure of Atom
The structure of the atom is a fundamental concept in chemistry and physics that describes the arrangement of subatomic particles within an atom. The modern understanding of atomic structure is based on the development of quantum mechanics and various experimental observations.

Sub-atomic Particles

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Discovery Of Electron

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Charge To Mass Ratio Of Electron

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Charge On The Electron

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Discovery Of Protons And Neutrons

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Introduction

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Thomson Model Of Atom

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Rutherfords Nuclear Model Of Atom

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Atomic Number And Mass Number

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Isobars And Isotopes

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Drawbacks Of Rutherford Model

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Introduction

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Wave Nature Of Electromagnetic Radiation

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Particle Nature Of Electromagnetic Radiation: Plancks Quantum Theory

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Photoelectric Effect

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Evidence For The Quantized* Electronic Energy Levels: Atomic Spectra

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Emission and Absorption Spectra

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Line Spectrum of Hydrogen

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Introduction

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Explanation Of Line Spectrum Of Hydrogen

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Limitations Of Bohrs Model

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Introduction

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Dual Behaviour Of Matter

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Heisenbergs Uncertainty Principle

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Significance of Uncertainity Principle

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Reasons for Failure of Bohr’s Model

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Introduction

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Orbitals And Quantum Numbers

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Shapes Of Atomic Orbitals

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Energies Of Orbitals

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Filling Of Orbitals In Atom

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Aufbau Principle

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Pauli Exclusion Principle

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Hund’s Rule of Maximum Multiplicity

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Electronic Configuration Of Atoms

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Stability Of Completely Filled And Half Filled Subshells.

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Structure of Atom

4.Classification of Elements and Periodicity in Properties
"Classification of Elements and Periodicity in Properties" refers to the organization of chemical elements based on their properties and the patterns that emerge when elements are arranged in a systematic manner. This organization is primarily manifested in the Periodic Table, which is a tabular arrangement of elements based on their atomic number, electron configuration, and recurring chemical properties.

Why Do We Need To Classify Elements?

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Genesis Of Periodic Classification

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Modern Periodic Law And The Present Form Of The Periodic Table

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Nomenclature Of Elements With Atomic Numbers > 100

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Electronic Configurations Of Elements And The Periodic Table

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Electronic Configuration in Periods

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Groupwise Electronic Configurations

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Electronic Configurations And Types Of Elements: 5-, P-, D-, F- Blocks Ex

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The S-block Elements

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The P-block Elements

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The D-block Elements (Transition Elements)

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The F-block Elements (Inner-transition Elements)

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Metals, Non-metals And Metalloids

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Periodic Trends In Properties Of Elements

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Trends in Physical Properties(Atomic Radius,Ionic Radius ,Ionization Enthalpy,Electron Gain Enthalpy,Electronegativity)

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Periodic Trends In Chemical Properties

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Periodic Trends And Chemical Reactivity.

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Classification of Elements and Periodicity in Properties

5. Chemical Bonding and Molecular Structure
Chemical Bonding and Molecular Structure" is a fundamental concept in chemistry that explains how atoms come together to form molecules through the sharing or transfer of electrons. This concept is crucial for understanding the properties, behavior, and interactions of substances.

Introduction Chemical Bonding and Molecular Structure

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Octet Rule

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Limitation of Octet Rule

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Covalent Bonds

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Lewis Representation of Simple Molecules

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Formal Charge

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Introduction

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Lattice Enthalpy

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Bond Length

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Bond Angle

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Bond Enthalpy(bond energy)

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Bond Order

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Resonance Structures

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Polarity Of Bonds

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The Valence Shell Electron Pair Repulsion (VSEPR) Theory

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Valence Bond Theory

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Orbital Overlap Concept

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Directional Properties Of Bonds

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Overlapping Of Atomic Orbitals

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Types Of Overlapping And Nature Of Covalent Bonds(sigma,ss,pp,pi)

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The Strength Of Sigma And Pi Bonds

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Introduction

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Types Of Hybridisation(sp,sp2,sp3)

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Other Examples Of Sp3, Sp2 And Sp Hybridisation

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The Hybridisation Of Elements Involving D Orbitals

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Introduction

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Formation Of Molecular Orbitals Linear Combination Of Atomic Orbitals (Lcao)

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Conditions For The Combination Of Atomic Orbitals

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Types Of Molecular Orbitals

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Energy Level Diagram For Molecular Orbitals

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Electronic Configuration And Molecular Behaviour

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Bonding In Some Homonuclear Diatomic Molecules

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Hydrogen Bonding

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Cause Of Formation Of Hydrogen Bond

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Types Of H-bonds.

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Chemical Bonding and Molecular Structure

6.States of Matter
"States of Matter" refer to the different physical forms that matter can exist in based on factors such as temperature and pressure. There are four primary states of matter: solid, liquid, gas, and plasma. Each state has distinct characteristics that arise from the arrangement and motion of particles.

Intermolecular Forces

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Dispersion Forces Or London Forces

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Dipole-dipole Forces

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Dipole-induced Dipole Forces

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Hydrogen Bond

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Thermal Energy

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Intermolecular Forces Vs Thermal Interactions

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The Gaseous State Ex

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The Gas Laws Ex

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Boyles Law (Pressure-volume Relationship)

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Charles Law (Temperature-volume Relationship)

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Gay Lussacs Law (Pressure-temperature Relationship)

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Avogadro Law (Volume Amount Relationship)

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Introduction

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Density And Molar Mass Of A Gaseous Substance

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Daltons Law Of Partial Pressures

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Kinetic Molecular Theory Of Gases

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Behaviour Of Real Gases: Deviation From Ideal Gas Behaviour

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Liquefaction Of Gases

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Liquid State

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Vapour Pressure

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Surface Tension and Viscosity.

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7.Thermodynamics
Thermodynamics is a branch of physics that deals with the relationships between heat, work, temperature, energy, and other macroscopic properties of matter. It provides a framework for understanding and predicting the behavior of systems composed of a large number of particles, such as gases, liquids, and solids, without delving into the microscopic details of individual particles.

Thermodynamic Terms

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The System and the Surroundings

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Types of Thermodynamic Systems(open,closed,Isolated)

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State of the System(work,heat,the general case)

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Internal Energy as a State Function

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Work

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Enthalpy, H

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State Function

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Extensive and Intensive Properties

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Heat Capacity

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Relationship Between Cp and CV

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Measurement Of ”U And ”H: Calorimetry

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Enthalpy Change and Reaction Enthalpy

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Standerd Enthalpy Reactions

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Enthalpy Change during Phase transformation

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Standerd Enthalpy of Formation

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Hess’s Law of Constant Heat Summation

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Enthalpy of combustion

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Enthalpy of atomization

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Bond Enthalpy

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Enthalpy of Solution

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Lattice Enthalpy

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Entropy and Spontaneity

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Gibbs Energy and Spontaneity

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Gibbs Energy Change And Equilibrium

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8. Chemical Equilibrium
Chemical equilibrium is a fundamental concept in chemistry that describes the state of a chemical reaction in which the concentrations of reactants and products remain constant over time. In other words, the forward and reverse reactions are occurring at the same rate, resulting in no net change in the overall concentrations of the substances involved. This does not mean that the reactions have stopped; rather, they are proceeding in both directions at equal rates.

Solid-liquid Equilibrium

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Liquid-vapour Equilibrium

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Solid Vapour Equilibrium

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Equilibrium Involving Dissolution Of Solid Or Gases In Liquids

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General Characteristics Of Equilibria Involving Physical Processes

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Equilibrium In Chemical Processes Dynamic Equilibrium

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Law Of Chemical Equilibrium And Equilibrium Constant

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Homogeneous Equilibria

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Equilibrium Constant In Gaseous Systems

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Heterogeneous Equilibria

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Applications Of Equilibrium Constants

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Predicting The Extent Of A Reaction

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Predicting The Direction Of The Reaction

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Calculating Equilibrium Concentrations

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Relationship Between Equilibrium Constant K, Reaction Quotient Q And Gibbs Energy G

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Effect Of Concentration Change

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Effect Of Pressure Change

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Effect Of Inert Gas Addition

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Effect Of Temperature Change

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20.Effect Of A Catalyst

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9. Redox Reactions
Redox reactions, also known as oxidation-reduction reactions, are fundamental chemical processes in which there is a transfer of electrons between reactants. These reactions involve the concepts of oxidation and reduction, which are complementary processes

Classical Idea Of Redox Reactions Oxidation And Reduction Reactions and agents

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Redox Reactions In Terms Of Electron Transfer Reactions

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Competitive Electron Transfer Reactions

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Oxidation Number

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Types Of Redox Reactions

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Balancing Of Redox Reactions

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Redox Reactions As The Basis For Titrations

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Limitations Of Concept Of Oxidation Number

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Stock notation

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Redox Reactions And Electrode Processes.

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10 Hydrogen
Redox reactions, also known as oxidation-reduction reactions, are fundamental chemical processes in which there is a transfer of electrons between reactants. These reactions involve the concepts of oxidation and reduction, which are complementary processes.

Position Of Hydrogen In The Periodic Table

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Dihydrogen, H2

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Occurrence

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Isotopes Of Hydrogen

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Preparation Of Dihydrogen, H2

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Laboratory Preparation Of Dihydrogen

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Commercial Production Of Dihydrogen

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Properties Of Dihydrogen

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Physical Properties

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Chemical Properties

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Uses Of Dihydrogen

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Hydrides

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Ionic Or Saline Hydrides

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Covalent Or Molecular Hydride

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Metallic Or Non-stoichiometric (Or Interstitial ) Hydrides

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Introduction

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Physical Properties Of Water Ex

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Structure Of Water

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Structure Of Ice

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Chemical Properties Of Water

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Hard And Soft Water

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Temporary Hardness

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Permanent Hardness

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Hydrogen Peroxide (H202)

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Preparation

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Physical Properties

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Structure

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Chemical Properties

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Storage

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Uses

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Heavy Water, D20

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Dihydrogen as a Fuel

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11.The s-Block Elements
The s-block elements are a group of chemical elements located in the first two columns of the periodic table, consisting of Group 1 (alkali metals) and Group 2 (alkaline earth metals). These elements have their outermost electrons in the s subshell of their electron configuration. The s-block elements exhibit several common characteristics and trends due to their similar electronic configurations. Here's some information about the s-block elements.

Introduction

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Group 1 Elements: General introduction

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Group 2 Elements: General introduction

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electronic configuration and general trends in physical properties of elements

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electronic configuration and general trends in chemical properties of elements

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anomalous properties of the first element of each group

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diagonal relationships

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Preparation and properties of some important compounds: sodium carbonate

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Preparation and properties of some important compounds: sodium chloride

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Preparation and properties of some important compounds: sodium hydroxide

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Preparation and properties of some important compounds: sodium hydrogen carbonate

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Industrial uses of lime

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Industrial uses of limestone

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Industrial uses of Plaster of Paris

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Industrial uses of cement

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The biological significance of Na, K, Mg and Ca

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12.The p-Block Elements
The p-block elements are a diverse group of chemical elements located in the periodic table's groups 13 to 18, encompassing elements from boron (Group 13) to noble gases (Group 18). These elements have their outermost electrons in the p subshell of their electron configuration. The p-block elements exhibit a wide range of properties and behaviors due to their varying electronic configurations. Here's some information about the p-block elements.

General Introduction of p block elements

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Group 13 Elements: The Boron Family

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1. Electronic Configuration

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2. Atomic Radii

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3. Ionization Enthalpy

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4. Electronegativity

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5. Physical Properties

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6. Chemical Properties

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2. Important Trends And Anomalous Properties Of Boron

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1. Borax

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2. Orthoboric Acid

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3. Diborane, B2h6

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4. Uses Of Boron And Aluminium And Their Compounds

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5. Group 14 Elements: The Carbon Family

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1. Electronic Configuration

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2. Covalent Radius

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2. Covalent Radius

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3. Ionization Enthalpy

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4. Electronegativity

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5. Physical Properties

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6. Chemical Properties

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6. Important Trends And Anomalous Behaviour Of Carbon

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7. Allotropes Of Carbon

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1. Diamond

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2. Graphite

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3. Fullerenes

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4. Uses Of Carbon

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8. Some Important Compounds Of Carbon And Silicon

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1. Carbon Monoxide

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2. Carbon Dioxide

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3. Silicon Dioxide, Si02

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4. Silicones

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5. Silicates

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6. Zeolites

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13.Organic Chemistry Some Basic Principles and Techniques
The p-block elements are a diverse group of chemical elements located in the periodic table's groups 13 to 18, encompassing elements from boron (Group 13) to noble gases (Group 18). These elements have their outermost electrons in the p subshell of their electron configuration. The p-block elements exhibit a wide range of properties and behaviors due to their varying electronic configurations.

1. General Introduction

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Tetravalence Of Carbon: Shapes Of Organic Compounds

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Introduction

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1. Complete, Condensed And Bond-line Structural Formulas

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2. Three-dimensional Representation Of Organic Molecules

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Classification Of Organic Compounds

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Nomenclature Of Organic Compounds

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The IUPAC System Of Nomenclature

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IUPAC Nomenclature Of Alkanes

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Nomenclature Of Organic Compounds Having Functional Group(S)

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Nomenclature Of Substituted Benzene Compounds

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Introduction

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Structural Isomerism

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Chain or Nuclear Isomerism

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Position Isomerism

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Ring Chain Isomersim

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Functional Isomersim

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Metamerism Isomerism

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Geometrical Isomerism

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Optical Isomerism of Tartaric Acid

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Optical Isomerism of Lactic Acid

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Stereoisomerism

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1. Fission Of A Covalent Bond

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2. Nucleophiles And Electrophiles

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3. Electron Movement In Organic Reactions

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4. Electron Displacement Effects In Covalent Bonds

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5. Inductive Effect

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6. Resonance Structure

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7. Resonance Effect

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8. Electromeric Effect (E Effect)

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9. Hyperconjugation

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10. Types Of Organic Reactions And Mechanisms

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Introduction

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1. Sublimation

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2. Crystallization

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3. Distillation

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4. Differential Extraction

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5. Chromatography

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Introduction

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1. Detection Of Carbon And Hydrogen

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2. Detection Of Other Elements

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Introduction

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1. Carbon And Hydrogen

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2. Nitrogen

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3. Halogens

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4. Sulphur

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5. Phosphorus

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6. Oxygen

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14.Hydrocarbon
Hydrocarbons are organic compounds composed exclusively of hydrogen (H) and carbon (C) atoms. They are the simplest type of organic compounds and serve as the fundamental building blocks for more complex organic molecules found in living organisms and various natural and synthetic materials. Hydrocarbons can be classified into two main categories: aliphatic hydrocarbons and aromatic hydrocarbons.

Classification of Hydrocarbon-1. Nomenclature And Isomerism

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2. Preparation

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3. Properties(physical and chemical )

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4. Conformations

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Introduction-1. Structure Of Double Bond

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2. Nomenclature

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3. Isomerism

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4. Preparation

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3. Properties(physical and chemical )

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Introduction – 1. Nomenclature And Isomerism

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2. Structure Of Triple Bond

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3. Preparation

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3. Properties(physical and chemical )

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Introduction – 1. Nomenclature And Isomerism

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2. Structure Of Benzene

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3. Aromaticity

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4. Preparation Of Benzene

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5. Properties(chemical and physical )

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6. Directive Influence Of A Functional Group In Monosubstituted Benzene

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Carcinogenicity And Toxicity

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15. Environmental Chemistry
Environmental chemistry is a branch of chemistry that focuses on the study of chemical processes occurring in the environment, including the natural world and the impacts of human activities on the environment. It aims to understand the behavior, fate, and effects of various chemical substances in air, water, soil, and living organisms. Environmental chemistry plays a critical role in addressing environmental issues and developing sustainable solutions.

Environmental Pollution

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Introduction and its Types -1. Tropospheric Pollution

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2. Stratospheric Pollution

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Introduction and its Types – 1. Causes of Water Pollution

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2. International Standards for Drinking Water

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Introduction and its Types -1. Pesticides

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Industrial Waste

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Strategies To Control Environmental Pollution

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1. Waste Management

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2. Waste Management

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Green Chemistry

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1. Introduction

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2. Green Chemistry in day-to-day Life

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16.Solid State
Solid-state chemistry is a branch of chemistry that focuses on the study of solid materials and their properties. Solids are one of the three classical states of matter, and solid-state chemistry delves into the arrangement, structure, bonding, and behavior of atoms, ions, or molecules within solids. This field is essential for understanding the properties and applications of materials in various scientific, technological, and industrial contexts

Introduction to Solid State and its Classification

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Crystalline Solids

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Amorphous Solids

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Molecular Solids

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Ionic Solids

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Metallic Solids

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Covalent Solids

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Bravais Lattice

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Primitive and Centred Unit Cells

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Problems Based on Crystal Lattices and Unit Cells

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Primitive Cubic Unit Cell

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Body – Centred Cubic Unit Cell

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Face -Centred Cubic Unit Cell

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Problems Based on Number of Atoms in a Unit Cell

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Introduction to Closed Packed Structures(Closed Packing in one dimension,Close Packing in Two Dimension,Close Packing in Three Dimension,

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Formula of a Compound and Number of Voids Filled

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Packing Efficiency in hcp and ccp Structures

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Efficiency of Packing in Body – Centred Cubic Structures

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Packing Efficiency in Simple Cubic Lattice

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Problems Based on Packing Efficiency

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Calculation Involving Unit Cell Dimension

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Introduction Types of Point Defects(Stiochiometric,Vacancy,Interstitial,Frenkel,Schottky,Impurity,Non-stiochometric,Metal Excess,Metal Deficiency)

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Conduction of Electricity in Metals

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Conduction of Electricity in Semiconductors(electron rich,electron deficit)

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Application of n type and p type semiconductors

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Magnetic Properties(para,dia,ferro,antiferro,ferri)

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17.Solutions
A solution is a homogeneous mixture composed of two or more substances that are uniformly distributed at the molecular or atomic level. In a solution, the components are thoroughly mixed, and there is no visible separation between them. Solutions can exist in various physical states, including gaseous solutions (like air), liquid solutions (like sugar dissolved in water), and solid solutions (like alloys). Solutions are a fundamental concept in chemistry and have widespread applications in various scientific, industrial, and everyday contexts.

Types of Solutions

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Expressing Concentration of Solutions

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Introduction

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1. The solubility of a Solid in a Liquid

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2. The solubility of a Gas in a Liquid

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Introduction -1. Vapour Pressure of Liquid-Liquid Solutions

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2. Raoults Law as a special case of Henrys Law

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3. Vapour Pressure of Solutions of Solids in Liquids

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Introduction – 1. Ideal Solutions

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2. Non-ideal Solutions

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Introduction – 1. Relative Lowering of Vapour Pressure

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2. Elevation of Boiling Point

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3. Depression of Freezing Point

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4. Osmosis and Osmotic Pressure

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Abnormal Molar Masses

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Von’t Hoff factor

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18.Electrochemistry
Electrochemistry is a branch of chemistry that deals with the relationship between electricity and chemical reactions. It involves the study of processes in which chemical changes are accompanied by the movement of electrons. Electrochemistry is fundamental to understanding various natural phenomena and has practical applications in fields like energy storage, corrosion prevention, and electroplating. Here's an overview of key concepts in electrochemistry

Electrochemical Cells

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Introduction

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1. Measurement of Electrode Potential

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Introduction

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1. Equilibrium Constant from Nernst Equation

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2. Electrochemical Cell and Gibbs Energy of Reaction

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Introduction

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1. Measurement of the Conductivity of Ionic Solutions

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2. Variation of Conductivity and Molar Conductivity with Concentration

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Introduction – 1. Products of Electrolysis

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1. Primary Batteries

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2. Secondary Batteries

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Fuel Cells

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Corrosion

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Faraday’s Law

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19. Chemical Kinetics
Chemical kinetics is the branch of chemistry that deals with the study of the rates of chemical reactions, the factors that influence these rates, and the mechanisms by which reactions occur. It provides insight into how reactants transform into products over time and helps us understand the underlying processes that drive these transformations.

Introduction

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The rate of a Chemical Reaction

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1. Dependence of Rate on Concentration

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2. Rate Expression and Rate Constant

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3. Order of a Reaction

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4. Molecularity of a Reaction

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Introduction – 1. Zero Order Reactions

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2. First-Order Reactions

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3. Half-Life of a Reaction

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4. Pseudo First Order Reaction

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5. Temperature Dependence of the Rate of a Reaction

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Effect of Catalyst

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Collision Theory of Chemical Reactions

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20.Surface Chemistry
Surface chemistry is a branch of chemistry that deals with the study of phenomena that occur at the interface between two phases, usually involving a solid phase (such as a solid surface or a particle) and a liquid or gaseous phase. It focuses on understanding the behavior of molecules and atoms at surfaces and interfaces, which can significantly differ from their behavior in bulk.

Introduction

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1. The distinction between Adsorption and Absorption

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2. Mechanism of Adsorption

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3. Types of Adsorption

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4. Adsorption Isotherms

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5. Adsorption from Solution Phase

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6. Applications of Adsorption

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Introduction – 1. Homogeneous and Heterogeneous Catalysis

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2. Adsorption Theory of Heterogeneous Catalysis

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3. Shape-Selective Catalysis by Zeolites

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4. Enzyme Catalysis

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5. Catalysts in Industry

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3. Colloids

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Introduction – 1. Classification Based on the Physical State of Dispersed Phase and Dispersion Medium

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2. Classification Based on the Nature of Interaction between Dispersed Phase and Dispersion Medium

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3. Classification Based on the Type of Particles of the Dispersed Phase, Multimolecular, Macromolecular, and Associated Colloids

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4. Preparation of Colloids

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5. Purification of Colloidal Solutions

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6. Properties of Colloidal Solutions

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Emulsions

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Colloids around Us

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21.General Principles and Processes of Isolation of Elements
The isolation of elements refers to the processes and techniques used to obtain pure elements from their naturally occurring sources, such as ores, minerals, or other compounds. This is often necessary because elements are rarely found in their pure form in nature and are usually mixed with other substances. The process of isolating elements involves various physical and chemical methods, each tailored to the specific properties of the element and the compound it is present in. Here are some general principles and processes commonly used for the isolation of elements

Occurrence of Metals

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Introduction

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Magnetic Separation

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Froth Float Method

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Hydraulic Washing

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Leaching

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Introduction

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Conversion to Oxide

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Reduction to Oxide to the Metal

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Thermodynamic Principles of Metallurgy

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Electrochemical Principles of Metallurgy

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Oxidation-Reduction

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Refining

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Distillation

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Liquation

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Electrolysis

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Zone Refining

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Vapour Phase Refining

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Chromatographic Methods

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Uses of Aluminium, Copper, Zinc, and Iron

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22.The p Block Elements – Group 15,16,17 and 18 groups
Certainly, let's delve into the p-block elements in Groups 15, 16, 17, and 18 of the periodic table, along with some descriptions of their characteristics

Group 15 Elements

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Electronic Configuration

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General Trends in Physical Properties of Elements Across the Periods and Down the Groups

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General Trends in Chemical Properties of Elements Across the Periods and Down the Groups

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Dinitrogen

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Ammonia

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Oxides of Nitrogen

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Nitric Acid

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Phosphorus Allotropic Forms

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Phosphine

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Phosphorus Halides

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Oxoacids of Phosphorus

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Group 16:general Introduction

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Electronic Configuration

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General Trends in Physical Properties of Elements Across the Periods and Down the Groups

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General Trends in Chemical Properties of Elements Across the Periods and Down the Groups

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Unique Behaviour of the First Element in Each Group

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Groupwise Study of the P Block Elements

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Simple Oxides

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Ozone

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Sulphur Allotropic Forms

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Sulphur Dioxide

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Oxoacids of Sulphur

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Sulphuric Acid

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Introduction

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Chlorine

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Hydrogen Chloride

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Oxoacids of Halogens

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Interhalogen Compounds

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Group 18: General Introduction

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Electronic Configuration

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General Trends in Physical Properties of Elements Across the Periods and Down the Groups

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General Trends in Chemical Properties of Elements Across the Periods and Down the Groups

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Unique Behaviour of the First Element in Each Group

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Groupwise Study of the P Block Elements

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Occurrence and Uses of Noble Gases

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Structures of Fluorides and Oxides of Xenon

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23. d and f Block Elements
Certainly, let's explore the d-block and f-block elements and provide a description of their characteristics

Position in the Periodic Table

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Electronic Configuration

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Occurrence and Characteristics

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General Trends in Properties of the First-Row Transition Elements: Physical Properties

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General Trends in Properties of the First-Row Transition Elements:ionization Enthalpy

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General Trends in Properties of the First-Row Transition Elements:oxidation States

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General Trends in Properties of the First-Row Transition Elements:atomic Radii

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General Trends in Properties of the First-Row Transition Elements:colour

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General Trends in Properties of the First-Row Transition Elements:catalytic Behaviour

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General Trends in Properties of the First-Row Transition Elements:magnetic Properties

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Complex Formation

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Interstitial Compounds

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Alloy Formation.

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Preparation, Properties, and Uses of K2Cr2O7 and KMnO4.

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Preparation, Properties, and Uses ofKMnO4.

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Lanthanides

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Electronic Configuration

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Oxidation States

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Chemical Reactivity

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Lanthanoid Contraction

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Electronic Configuration and Oxidation States

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Some Applications of d- and f-Block Elements

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24.Coordination Compounds
Coordination compounds, also known as complex compounds, are molecules that consist of a central metal atom or ion surrounded by a group of surrounding atoms, ions, or molecules known as ligands. These ligands are typically attached to the central metal through coordinate covalent bonds, where one or more pairs of electrons are donated by the ligand to the metal atom or ion.

Introduction to Coordination Compounds

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Werners Theory

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Ligands

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Coordination Number

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Denticity

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Chelation

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IUPAC Nomenclature of Mononuclear Coordination Compounds

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Isomerism in Coordination Compounds

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Bonding in Coordination Compounds

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Bonding in Metal Carbonyls

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Colour and Magnetic Properties

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Stability of Coordination Compounds

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Importance and Applications of Coordination Compounds.

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25.Haloalkanes and Haloarenes
Haloalkanes and haloarenes are types of organic compounds that contain halogen atoms (fluorine, chlorine, bromine, or iodine) bonded to carbon atoms. They are important classes of compounds with distinct properties and applications.

Introduction(Classification and structural isomerism)

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Nomenclature

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Nature of C-X Bond

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Methods of Preparation

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Physical Properties

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Chemical Properties- I

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Chemical Properties- II

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Aryl Halides : Introduction and Properties

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Aryl Halides Ring Substitution Reactions

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Mechanisms of Substitution Reactions

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Uses

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Environmental Effects of Dichloromethane

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Environmental Effects of Carbontetrachloride

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Environmental Effects of Chloroform

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Environmental Effects of Iodoform

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Environmental Effects of Freons

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Environmental Effects of Ddt

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26.Alcohols, Phenols and Ethers
Alcohols are organic compounds that contain a hydroxyl (-OH) functional group attached to a carbon atom. The general formula for an alcohol is R-OH, where R represents an alkyl or aryl group. Phenols are organic compounds in which a hydroxyl group (-OH) is directly attached to an aromatic ring. Unlike alcohols, which are usually aliphatic (non-aromatic) compounds, phenols possess unique chemical and physical properties due to the presence of the aromatic ring. Ethers are organic compounds characterized by an oxygen atom bonded to two alkyl or aryl groups.

Introduction

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Classification

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Nomenclature

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Structures of Functional groups

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Introduction 1 -Alcohols

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Identification of Primary

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Secondary and Tertiary Alcohols

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Mechanism of Dehydration

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Preparation Techniques of Alcohols

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Physical Properties – Alcohols

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Chemical Properties – Alcohols

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Introduction 2 -Phenols

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Acidic Nature

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Electrophilic Substitution Reactions

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Halogenation

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Nitration

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Sulphonation

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Reimer Tiemann Reaction

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Physical and chemical Properties of phenol

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Introduction 3 – Ether

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Structure

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Preparation Techniques of Ethers

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Physical Properties – Ethers

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Chemical Properties – Ethers

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Some Important Commercially Alcohols

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27.Aldehydes, Ketones and Carboxylic Acids
Aldehydes are a class of organic compounds that feature a carbonyl group (-C=O) bonded to a hydrogen atom and an alkyl or aryl group. The carbonyl group is typically located at the end of a carbon chain. Aldehydes are named with the suffix "-al" and are often denoted by the general formula RCHO, where R represents an alkyl or aryl group. Ketones are organic compounds that possess a carbonyl group (-C=O) bonded to two alkyl or aryl groups. The carbonyl group is situated within the carbon chain. Ketones are named with the suffix "-one" and are generally represented by the formula RCOR', where R and R' are alkyl or aryl groups. Carboxylic acids are organic compounds containing a carboxyl group (-COOH), which consists of a carbonyl group (-C=O) bonded to a hydroxyl group (-OH). Carboxylic acids are named with the suffix "-oic acid" and are denoted by the general formula RCOOH, where R is an alkyl or aryl group.

Nomenclature and Structure of Carbonyl Group

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Nature of Carbonyl Group

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Physical and chemical Properties of aldehydes and ketones

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Nucleophilic Addition to >C=O Group

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Relative Reactivities of Aldehydes and Ketones

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Nucleophilic Addition Reactions (Addition of Hcn, Nh3 and Its Derivatives)

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Uses of Aldehydes and Ketones

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Nomenclature and Structure of Carboxyl Group

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Methods of Preparation of Carboxylic Acids

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Physical and chemical Properties

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Chemical Reactions

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Uses of Carboxylic Acids

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Carboxylic Acids: Acidic Strength and Factors Affecting It

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Chemical Tests to Distinguish Between Aldehydes and Ketones

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28.Amines
Amines are a class of organic compounds characterized by the presence of the amino functional group (NH2) in their chemical structure. They are considered derivatives of ammonia (NH3) in which one or more hydrogen atoms are replaced by organic substituents. Amines play a vital role in various biological, industrial, and medicinal processes.

Structure of Amines

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Classification

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Nomenclature

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Preparation of Amines

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Physical and Chemical Properties

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Chemical Reactions

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Methods of preparation of Diazonium Salts

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Physical Properties

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Chemical reactions

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Importance of Diazonium salts in Synthesis of aromatic Compounds

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29.Biomolecules
Biomolecules are organic molecules that play essential roles in living organisms. They are the building blocks of life and are involved in various biological processes, including metabolism, growth, reproduction, and communication within cells. There are four main classes of biomolecules: carbohydrates, lipids, proteins, and nucleic acids.

Introduction

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General Introduction and Importance of Biomolecules

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Classification: Aldoses and Ketoses

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Monosaccharides (Glucose and Fructose)

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Constituent Monosaccharides or Oligosaccharides (Sucrose, Lactose, Maltose)

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Polysaccharides (Starch, Cellulose, Glycogen)

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Proteins: Elementary Idea of Amino Acids

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Peptide Bond

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Polypeptides

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Proteins: Primary, Secondary, Tertiary and Quaternary Structure (Qualitative Idea Only)

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Denaturation of Proteins

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Enzymes

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Vitamins: Classification and Functions

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B Chemical Constitution of Dna and Rna

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Biological Functions of Nucleic Acids

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Nuclei Acids

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Hormones

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30.Polymers
Polymers are large molecules made up of repeating subunits called monomers. These molecules are essential components of many materials that we encounter in our daily lives. They can be natural or synthetic and are found in a wide range of products, from plastics and textiles to proteins and DNA.

Introduction

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Classification of Polymers

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Molecular Mass of Polymers

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Addition and Condensation

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Co-Polymerization

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Natural and Synthetic Rubber and Vulcanization.

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Biodegradable Polymers

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Polyethene

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Nylon

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Polyester

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Bakelite

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31.Chemistry in Everyday Life
Chemistry plays a vital role in our everyday lives, influencing countless aspects of our routines and interactions. From the food we eat to the products we use and the environment we inhabit, chemistry's impact is profound.

Introduction

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Drugs and their Classification

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Analgesics

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Tranquilizers

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Antiseptics

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Disinfectants

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Antimicrobials

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Antifertility Drugs

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Antibiotics

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Antacids

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Preservatives

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Artificial Sweetening Agents Common Examples

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Cleansing Agents: Soaps and Detergents

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Cleansing Action

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Antihistamines Their Meaning and Common Examples

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Fertilizers

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32.Nuclear Chemistry and Radioactivity
Nuclear chemistry is a branch of chemistry that deals with the study of nuclear processes, including the behavior of radioactive substances and the changes that occur within atomic nuclei. Radioactivity is a fundamental concept in nuclear chemistry, referring to the spontaneous emission of particles or radiation from unstable atomic nuclei. This phenomenon was first discovered by Henri Becquerel in 1896 and later explained by Marie Curie and her husband Pierre Curie.

Introduction

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Even and odd nature of proton and neutron

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neutron to Proton ratio,magic numbers

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Nuclear Potential

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Nuclear Binding energy and mass defect

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Radioactivity

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Rate of decay

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Rate Law

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Expression for decay constant

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Half life of radio element

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Graphical representation of decay

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Units of radioactivity

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Alpha decay

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Beta decay

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Gamma decay

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Transmutation

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Comparison between chemical reaction and nuclear reaction

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Induced or artifical radioactivity

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Nuclear fission and Nuclear fusion

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Radiocarbon dating

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Electrical energy from nuclear fission

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Application in medicine and other applications

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33.Ionic Equilibrium
Ionic equilibrium is a concept in chemistry that relates to the balance between ions in a solution. It deals with the behavior of ions and the interactions between positively and negatively charged species in aqueous solutions. In particular, it focuses on the equilibrium that is established between ionic compounds when they dissolve in water, leading to the formation of ions.

Introduction

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Ionic Equilibrium In Solution

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Arrhenius Concept Of Acids And Bases

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The Bronsted-lowry Acids And Bases

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Lewis Acids And Bases

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Ionization Of Acids And Bases

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The Ionization Constant Of Water And Its Ionic Product

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The Ph Scale

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Ionization Constants Of Weak Acids

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Ionization Of Weak Bases

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The Relation Between Ka And Kb

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Di- And Polybasic Acids And Di- And Polyacidic Bases

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Factors Affecting Acid Strength

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Hydrolysis Of Salts And The Ph Of Their Solutions

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Buffer Solutions

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Solubility Equilibria Of Sparingly Soluble Salts

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Solubility Product Constant

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Common Ion Effect On Solubility Of Ionic Salts.

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MHCET_CHEMISTRY

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Course Curriculum

1.Some Basic Concepts of Chemistry These foundational concepts include atomic structure, bonding, reactions, states of matter, solutions, acids and bases, and serve as the cornerstone for further exploration in the field of chemistry.

Importance Of Chemistry

Nature Of Matter

Laws Of Chemical Combinations

Law Of Conservation Of Mass

Law Of Definite Proportions

Law Of Multiple Proportions

Gay Lussacs Law Of Gaseous Volumes

Avogadro Law

Daltons Atomic Theory

Atomic And Molecular Masses

Atomic Mass, Average Atomic Mass

Mole Concept And Molar Masses

Some Basic Concepts Of Chemistry

Introduction Introduction to Analytical Chemistry

The International System Of Units (SI)

Mass, Weight,density and temperature

Introduction

Precision and Accuracy

Significant Figures

Dimensional Analysis

Percentage Composition

Empirical Formula For Molecular Formula

Introduction

Limiting Reagent

Reactions In Solutions.

Mass percent ,Mole Fraction,Molarity

Introduction to Analytical Chemistry

3. Structure of Atom The structure of the atom is a fundamental concept in chemistry and physics that describes the arrangement of subatomic particles within an atom. The modern understanding of atomic structure is based on the development of quantum mechanics and various experimental observations.

Sub-atomic Particles

Discovery Of Electron

Charge To Mass Ratio Of Electron

Charge On The Electron

Discovery Of Protons And Neutrons

Introduction

Thomson Model Of Atom

Rutherfords Nuclear Model Of Atom

Atomic Number And Mass Number

Isobars And Isotopes

Drawbacks Of Rutherford Model

Introduction

Wave Nature Of Electromagnetic Radiation

Particle Nature Of Electromagnetic Radiation: Plancks Quantum Theory

Photoelectric Effect

Evidence For The Quantized* Electronic Energy Levels: Atomic Spectra

Emission and Absorption Spectra

Line Spectrum of Hydrogen

Introduction

Explanation Of Line Spectrum Of Hydrogen

Limitations Of Bohrs Model

Introduction

Dual Behaviour Of Matter

Heisenbergs Uncertainty Principle

Significance of Uncertainity Principle

Reasons for Failure of Bohr’s Model

Introduction

Orbitals And Quantum Numbers

Shapes Of Atomic Orbitals

Energies Of Orbitals

Filling Of Orbitals In Atom

Aufbau Principle

Pauli Exclusion Principle

Hund’s Rule of Maximum Multiplicity

Electronic Configuration Of Atoms

Stability Of Completely Filled And Half Filled Subshells.

Structure of Atom

Why Do We Need To Classify Elements?

Genesis Of Periodic Classification

Modern Periodic Law And The Present Form Of The Periodic Table

Nomenclature Of Elements With Atomic Numbers > 100

Electronic Configurations Of Elements And The Periodic Table

Electronic Configuration in Periods

Groupwise Electronic Configurations

Electronic Configurations And Types Of Elements: 5-, P-, D-, F- Blocks Ex

The S-block Elements

The P-block Elements

The D-block Elements (Transition Elements)

1.Some Basic Concepts of Chemistry
These foundational concepts include atomic structure, bonding, reactions, states of matter, solutions, acids and bases, and serve as the cornerstone for further exploration in the field of chemistry.

3. Structure of Atom
The structure of the atom is a fundamental concept in chemistry and physics that describes the arrangement of subatomic particles within an atom. The modern understanding of atomic structure is based on the development of quantum mechanics and various experimental observations.