Grade 12
  1. Solid state  1.1. Classification of solids  1.2. Crystal Lattice and Unit Cell  1.3. Packing Efficiency  1.4. Density of unit cell  1.5. Imperfections in solids (point and line defects)  1.6. Electrical Properties of Solids (Conductors, Insulators and Semiconductors)  1.7. Magnetic Properties of Solids (Diamagnetic, Paramagnetic and Ferromagnetic Materials)
  2. Solution  2.1. Types of Solutions (Homogeneous and Heterogeneous)  2.2. Expressing concentration of solutions (mass %, volume %, molarity, molality, normality, mole fraction)  2.3. Solubility of solids and gases in liquids (Henry's law)  2.4. Raoult's Law and Ideal and Non-Ideal Solutions  2.5. Syndrome properties  2.6. Abnormal molar mass and Van't Hoff factor
  3. Electrochemistry  3.1. Electrochemical cells (galvanic and electrolytic cells)  3.2. Galvanic cell and EMF of the cell  3.3. Standard electrode potential and electrochemical series  3.4. Nernst equation and its applications  3.5. Conductivity and electrolytic cells (specific, molar and equivalent conductivity)  3.6. Kohlrausch's law and its applications  3.7. Batteries (primary and secondary cells)  3.8. Corrosion and its prevention
  4. Chemical kinetics  4.1. Rate of chemical reaction  4.2. Factors affecting the reaction rate (concentration, temperature, catalyst, surface area)  4.3. Order and molecularity of the reaction  4.4. Integrated Rate Equations (Zero, First and Second Order)  4.5. Half-life of a reaction  4.6. Collision theory and activation energy  4.7. Arrhenius equation and its applications
  5. Surface chemistry  5.1. Adsorption and its types (Physicosorption and Chemisorption)  5.2. Catalysis and its types (homogeneous and heterogeneous)  5.3. Colloids and their properties (Tyndall effect, Brownian motion, coagulation)  5.4. Emulsions and gels  5.5. Applications of Colloids
  6. General principles and processes of separation of elements  6.1. Presence of metals and minerals  6.2. Concentration of ores (gravity separation, froth flotation, magnetic separation)  6.3. Extraction of raw metals (roasting, calcination, reduction)  6.4. Thermodynamic and electrochemical principles of metallurgy  6.5. Refining of metals
  7. P-block elements  7.1. Group 15 elements (nitrogen and phosphorus)  7.2. Group 16 Elements (Oxygen, Sulphur and their Compounds)  7.3. Group 17 Elements (Halogens and their Compounds)  7.4. Group 18 Elements  7.5. Properties and Trends in p-Block Elements  7.6. Important compounds of p-block elements (ammonia, phosphine, sulphuric acid, hydrochloric acid)  7.7. Interhalogen compounds and their applications
  8. d-block and f-block elements  8.1. General Properties of Transition Metals  8.2. Properties of Inner Transition Metals (Lanthanoids and Actinoids)  8.3. Lanthanoid and actinoid contractions  8.4. Coordination Chemistry of d-Block Elements
  9. Coordination compounds  9.1. Werner's theory and modern concepts  9.2. Coordination number and type of ligand  9.3. Nomenclature of Coordination Compounds  9.4. Isomerism (geometrical and optical) in coordination compounds  9.5. Bonding in Coordination Compounds (Valence Bond Theory and Crystal Field Theory)  9.6. Stability and applications of coordination compounds in medicine and industry
  10. Haloalkanes and haloarenes  10.1. Classification and nomenclature of haloalkanes and haloarenes  10.2. Physical and Chemical Properties of Haloalkanes and Haloarenes  10.3. Mechanism of Nucleophilic Substitution Reactions (SN1 and SN2)  10.4. Uses and environmental effects (ozone depletion, CFCs)
  11. Alcohol, phenol and ether  11.1. Structure and classification of alcohols, phenols and ethers  11.2. Preparation and properties of alcohols  11.3. Preparation and properties of phenol  11.4. Preparation and properties of ethers  11.5. Chemical Reactions and Uses
  12. Aldehydes, ketones and carboxylic acids  12.1. Structure and nomenclature in aldehydes, ketones and carboxylic acids  12.2. Preparation and properties of aldehydes and ketones  12.3. Chemical reactions in aldehydes, ketones and carboxylic acids (nucleophilic addition, oxidation and reduction)  12.4. Preparation and Properties of Carboxylic Acids  12.5. Chemical Reactions and Uses of Carboxylic Acids
  13. Nitrogen-containing organic compounds  13.1. Amines (classification, structure, basicity)  13.2. Preparation and properties of amines  13.3. Reactions of Amines (Diazotization, Carbylamine Reaction)  13.4. Diazonium salts and their applications in paint industry
  14.1. Carbohydrates (classification and properties)  14.2. Proteins (Structure and Function)  14.3. Enzymes (Mechanism and Function)  14.4. Nucleic acids (DNA and RNA)  14.5. Vitamins and hormones
  15. Polymer  15.1. Classification of Polymers (Addition, Condensation, Copolymers)  15.2. Types of polymerization (free radical, ionic, condensation)  15.3. Important Polymers and Their Uses  15.4. Biodegradable and non-biodegradable polymers
  16. Chemistry in Everyday Life  16.1. Drugs and their classification (analgesics, antipyretics, antibiotics, antacids)  16.2. Chemicals in food and cosmetics (preservatives, artificial sweeteners, antioxidants)  16.3. Cleaning agents and detergents (soaps, synthetic detergents, surfactants)  16.4. Environmental Chemistry (Pollution, Green Chemistry, Sustainable Chemistry)

Grade 12d-block and f-block elements


Lanthanoid and actinoid contractions


Lanthanoid and actinoid contractions are important concepts in inorganic chemistry that deal with the gradual decrease in the size of atoms or ions of elements within the lanthanide series and actinide series. These contractions have significant effects on the chemical properties and reactivity of the elements, influencing their behavior in many complex ways. Let's take a deeper look at these phenomena.

Lanthanoid contraction

The lanthanoids, also called rare earth elements, are a series of 15 chemically similar metallic elements with atomic numbers from 57 to 71, between lanthanum (La) and lutetium (Lu) on the periodic table. Lanthanoid contraction refers to the steady decrease in their atomic and ionic radii as one proceeds down the series from lanthanum to lutetium.

This contraction in size occurs despite the increase in atomic number and is mainly due to the poor shielding effect of the 4f electrons, which do not effectively block the increased nuclear charge from pulling the outer electrons more tightly. As a result, the electrons are drawn closer to the nucleus, leading to a decrease in size.

Example: Comparing radii


Element: La Ce Pr Nd Atomic Number: 57 58 59 60 Ionic Radius (pm): 106 105 104 103 Element: Sm Eu Gd Tb Atomic Number: 62 63 64 65 Ionic Radius (pm): 102 101 100 99

Effect of lanthanoid contraction

Chemical Similarity: Due to lanthanoid contraction, the chemical properties of these elements are quite similar, making their separation difficult. Their similar radius and charge also result in similar behaviour in the formation of complex ions.

Increase in Density: As the atomic volume decreases with the successive addition of electrons and protons, the density of lanthanoids starts increasing.

Bond Strength: Contraction results in the formation of strong metallic bonds, leading to variation in melting point and hardness across the lanthanide series.

Visualization of lanthanoid contraction

La Ce Pr Nd Sm Eu Gd Atomic number → Atomic radius ←

Actinoid contraction

The actinoid contraction is similar to the lanthanoid contraction and occurs in the actinoid series - the elements with atomic numbers 89 to 103 between actinium (Ac) and lawrencium (Lr) on the periodic table. As one moves down the actinoid series, the atomic and ionic radii also decrease.

As in the lanthanoids, this contraction is due to ineffective shielding by the 5f electrons, which causes the nuclear charge to exert an increased attraction on the electrons. This brings the outer electron shell closer to the nucleus, leading to a gradual decrease in both atomic and ionic radii.

Example: Comparison of radii of actinoids


Element: Th Pa U Np Atomic Number: 90 91 92 93 Ionic Radius (pm): 110 109 108 107 Element: Pu Am Cm Bk Atomic Number: 94 95 96 97 Ionic Radius (pm): 106 105 104 103

Effect of actinoid contraction

Chemical reactivity: Like the lanthanoids, the actinoids have comparable chemical properties due to their similarities in size and charge, although they generally exhibit a wider range of oxidation states.

Metallurgical Properties: Contraction causes changes in metallic properties such as melting and boiling point, density and hardness.

Separation Difficulties: Due to their similarity in size, it is challenging to separate actinoids from one another by chemical means.

Visualization of actinoid contraction

Th Pa U Np Pu Am Cm Atomic number → Atomic radius ←

The reason behind the contraction

The f-block elements, which include both the lanthanoids and actinoids, exhibit this contraction slightly due to the poorer shielding effect of the f electrons compared to the d and s electrons. The f-electrons, being poorly effective in counteracting the pull of the nucleus, let the inner electrons feel a much stronger attraction to the nucleus. This means that as more electrons are added, they increase the overall positive nuclear charge without a corresponding increase in shielding, which in turn reduces the actual size of each subsequent atom.

Both lanthanoid and actinoid contractions affect many areas of chemistry and materials science. They affect the diffraction of new materials, which is a potential route to the discovery of new materials with potential applications in technology and industry.

Effect on transition elements: Even the transition metals, which are placed after the lanthanoids or actinoids in the periodic table, have their sizes affected by these contractions, further affecting the trends seen across different periods and groups.

Conclusion

In summary, the concepts of lanthanoid and actinoid contraction are important in understanding the periodic properties affecting the f-block elements. Both result in a steady decrease in atomic and ionic sizes across their respective series, raising complex and sometimes challenging questions about their chemical behavior and separation techniques. This contraction plays a role in shaping the modern materials we use and guides chemists and scientists in exploring further uses for these fascinating elements.


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Properties of Inner Transition Metals (Lanthanoids and Actinoids)
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Lanthanoid and actinoid contractions

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