Carbon and its Compounds — Class 10 Science

"Carbon is the backbone of life. From your DNA to the petrol in your car — all carbon."

1. About the Chapter

This chapter introduces ORGANIC CHEMISTRY — the chemistry of CARBON COMPOUNDS. Carbon has 10 million+ known compounds — more than all other elements combined!

Topics

• Carbon's unique properties (catenation, tetravalency)
• Covalent bonding
• Hydrocarbons (saturated/unsaturated)
• Functional groups
• IUPAC nomenclature
• Some important compounds (ethanol, ethanoic acid)
• Soaps and detergents

Why Important

• Foundation for Class 11-12 organic chemistry
• All life uses carbon compounds
• Petrochemical industry
• Pharmaceuticals
• Plastics, fuels, foods

2. Carbon's Unique Properties

Tetravalency

Carbon has 4 valence electrons. It needs 4 more to complete octet. To do this, it FORMS 4 COVALENT BONDS with other atoms.

This is tetravalency — carbon makes 4 bonds.

Catenation

Carbon atoms can BOND TO OTHER CARBON ATOMS forming chains or rings. This unique ability is called CATENATION.

This is why carbon has MILLIONS of compounds.

Why Carbon is Special

• Tetravalency: makes 4 bonds (lots of variety)
• Catenation: long chains and rings possible
• Forms stable bonds with H, N, O, S, halogens
• All life is built on carbon

3. Covalent Bonding

What is It?

A covalent bond = SHARING of electrons between atoms.

Example: H₂

Two hydrogen atoms each have 1 electron. They SHARE 2 electrons: H · + · H → H : H (or H-H)

Example: H₂O (water)

Oxygen has 6 valence electrons; needs 2 more. Each H shares 1 electron with O.

Single, Double, Triple Bonds

• Single (-): 1 pair shared (CH₄)
• Double (=): 2 pairs shared (CO₂, C=C in alkenes)
• Triple (≡): 3 pairs shared (N₂, C≡C in alkynes)

Properties of Covalent Compounds

• Generally LOW melting/boiling points
• Mostly INSOLUBLE in water (some exceptions)
• Don't conduct electricity (no ions)
• Can be solid, liquid, or gas at room temp

4. Hydrocarbons

Definition

Compounds containing only HYDROGEN and CARBON.

Types

Saturated Hydrocarbons (ALKANES):

• Only SINGLE bonds between carbons
• Formula: CₙH₂ₙ₊₂
• Examples: CH₄ (methane), C₂H₆ (ethane), C₃H₈ (propane)

Unsaturated Hydrocarbons:

Alkenes (one C=C double bond):

• Formula: CₙH₂ₙ
• Examples: C₂H₄ (ethene/ethylene), C₃H₆ (propene)

Alkynes (one C≡C triple bond):

• Formula: CₙH₂ₙ₋₂
• Examples: C₂H₂ (ethyne/acetylene), C₃H₄ (propyne)

5. Naming Hydrocarbons (IUPAC)

Names of Carbon Chains

Suffixes

• -ane: saturated (alkane), all single bonds
• -ene: alkene (one double bond)
• -yne: alkyne (one triple bond)

Examples

• 2-carbon alkane: ethane (C₂H₆)
• 2-carbon alkene: ethene (C₂H₄)
• 2-carbon alkyne: ethyne (C₂H₂)
• 4-carbon alkane: butane (C₄H₁₀)
• 4-carbon alkene: butene (C₄H₈)

6. Functional Groups

What is a Functional Group?

An ATOM or GROUP OF ATOMS that gives specific properties to a compound.

Important Functional Groups

7. Important Compounds

Ethanol (CH₃CH₂OH or C₂H₅OH)

• 'Alcohol' in drinks
• Also called ethyl alcohol or grain alcohol
• Made by fermentation of sugars (yeast)
• Used in: alcoholic drinks, antiseptic (>70% kills germs), solvent, fuel

Properties:

• Colourless liquid
• Boiling point 78°C
• Miscible with water
• Burns: C₂H₅OH + 3O₂ → 2CO₂ + 3H₂O

Ethanoic Acid (CH₃COOH or Acetic Acid)

• Common name: VINEGAR (dilute solution)
• 5-8% acetic acid solution in water = vinegar

Properties:

• Pungent smell
• Weak acid (pH ~3)
• Reacts with bases, carbonates
• Frozen below 16°C — 'glacial' acetic acid

8. Reactions of Ethanol

Combustion

C₂H₅OH + 3O₂ → 2CO₂ + 3H₂O (releases lots of energy)

Oxidation (with KMnO₄)

C₂H₅OH → CH₃COOH (alcohol becomes acid)

Dehydration (with H₂SO₄)

C₂H₅OH → C₂H₄ + H₂O (alcohol → alkene)

Esterification (with acid)

C₂H₅OH + CH₃COOH ↔ CH₃COOC₂H₅ + H₂O (produces 'ester' — fruity smell; used in perfumes)

9. Reactions of Ethanoic Acid

With Bases

NaOH + CH₃COOH → CH₃COONa + H₂O (sodium ethanoate)

With Carbonates

CH₃COOH + Na₂CO₃ → 2CH₃COONa + H₂O + CO₂↑

Esterification

CH₃COOH + C₂H₅OH ↔ CH₃COOC₂H₅ + H₂O (ester)

10. Soaps and Detergents

Soap

Sodium salt of long-chain fatty acid (R-COONa where R is long carbon chain).

How It Cleans

• Soap molecule has TWO parts:
  • Hydrophobic tail (hydrocarbon — repels water, attaches to oil/dirt)
  • Hydrophilic head (carboxylate — loves water)
• Forms MICELLES around dirt
• Water washes away the micelle

Limitation

Soap doesn't work well in HARD WATER (calcium, magnesium ions form precipitate — 'scum').

Detergents

Sodium salts of long-chain sulphonic acids or ammonium salts.

• Work in hard water
• More versatile
• Used in detergents, shampoos, cleaning agents
• Most synthetic; not always biodegradable (environmental issue)

11. Worked Examples

Example 1: Catenation

What is catenation? Give an example.

• Catenation = ability to form long chains/rings with same atom.
• Example: Carbon forms millions of compounds with C-C chains.

Example 2: Identify

Identify: CH₃-CH₂-OH

• Has 2 carbons, OH group → ethanol (ethyl alcohol)

Example 3: Saturated vs Unsaturated

Distinguish C₂H₆ and C₂H₄.

• C₂H₆ (ethane): saturated (only single bonds)
• C₂H₄ (ethene): unsaturated (has C=C double bond)

Example 4: Soap Working

Why doesn't soap clean in hard water?

• Hard water has Ca²⁺, Mg²⁺ ions.
• Soap reacts with these to form INSOLUBLE precipitates (scum).
• Less soap available for cleaning.
• Solution: use detergents (which don't form precipitates).

12. Common Mistakes

1. Carbon makes ionic bonds

   • NO. Carbon forms COVALENT bonds (sharing electrons).

2. All hydrocarbons are alkanes

   • WRONG. Three types: alkanes (single bonds), alkenes (double), alkynes (triple).

3. Methane is CH₂

   • WRONG. Methane is CH₄ (carbon forms 4 bonds).

4. Soap = detergent

   • DIFFERENT. Soap = sodium salt of fatty acid. Detergent = synthetic, works in hard water.

5. Ethanol is unsafe for drinking

   • It IS in alcoholic drinks (regulated). But METHANOL is poisonous.

13. Indian Context

Indian Pharmaceutical Industry

• 'Pharmacy of the world'
• Major exports of generic drugs
• All based on carbon compound chemistry

Indian Petroleum

• Reliance, IOCL produce petrol, diesel (hydrocarbons)
• Major economy contributor

Indian Polymer Industry

• Plastics, fibres, rubbers — all carbon compounds

14. Conclusion

Carbon and its Compounds open the door to ORGANIC CHEMISTRY:

• Tetravalency + Catenation = millions of compounds
• Hydrocarbons (alkanes, alkenes, alkynes)
• Functional groups add diversity
• Ethanol, ethanoic acid are key compounds
• Soaps and detergents clean our world

This chapter is FOUNDATIONAL for Class 11-12 organic chemistry. Practice 15+ problems.

Carbon: the element of life and modern civilisation.