Introduction to p-Block Elements

Groups 13 to 18 of the periodic table constitute the p-block. The last electron enters the p-orbital. This chapter focuses on Groups 13 and 14.

General Characteristics

  • General configuration: ns^2 np^(1-6).
  • Includes metals, non-metals, and metalloids.
  • Wide range of oxidation states.
  • Covalent character increases across period and up a group.

Group 13: Boron Family

B, Al, Ga, In, Tl.

General Properties

  • Electronic configuration: ns^2 np^1.
  • Common oxidation state: +3.
  • Tl shows +1 oxidation state (inert pair effect).
  • Boron is a metalloid; others are metals.
PropertyDown the Group
Atomic radiusIncreases
Ionisation enthalpyDecreases (but irregular)
Melting pointDecreases
ElectronegativityDecreases

Anomalous Behaviour of Boron

  • Non-metal (others are metals).
  • Forms covalent compounds (small size, high charge).
  • Does not form B^3+ ion.
  • Shows allotropy (amorphous and crystalline).
  • Forms boron hydrides (boranes).

Important Compounds of Boron

Borax (Na2B4O7.10H2O):

  • On heating: Na2B4O7 -> 2NaBO2 + B2O3.
  • B2O3 with CoO/NiO gives coloured beads (borax bead test).
  • Uses: In glass, enamel, as flux.

Boric Acid (H3BO3):

  • Weak monobasic acid (acts as Lewis acid).
  • B(OH)3 + H2O -> [B(OH)4]^- + H+.
  • Uses: Antiseptic, eyewash, flame retardant.

Aluminium

  • Most abundant metal in Earth's crust.
  • Amphoteric: reacts with acids and bases.
  • 2Al + 6HCl -> 2AlCl3 + 3H2.
  • 2Al + 2NaOH + 2H2O -> 2NaAlO2 + 3H2.
  • Used in alloys, foils, utensils, electrical cables.
  • Al2O3 (alumina): high melting point, used as abrasive.

Group 14: Carbon Family

C, Si, Ge, Sn, Pb.

General Properties

  • Electronic configuration: ns^2 np^2.
  • Common oxidation states: +4, +2.
  • Inert pair effect: stability of +2 increases down the group.
PropertyDown the Group
Atomic radiusIncreases
Ionisation enthalpyDecreases
Metallic characterIncreases
Maximum covalency4 (but Si can expand octet)

Allotropes of Carbon

Diamond:

  • sp^3 hybridised carbon.
  • Tetrahedral structure, very hard.
  • Electrical insulator, thermal conductor.
  • High refractive index.

Graphite:

  • sp^2 hybridised carbon.
  • Hexagonal layered structure.
  • Soft (layers slide), good conductor (delocalised electrons).
  • Used as lubricant and in pencils.

Fullerenes:

  • C60, C70, etc.
  • Soccer ball shape (12 pentagons, 20 hexagons).
  • Discovered in 1985 (Kroto, Smalley, Curl).

Carbon Compounds

CO2: Linear molecule. Dry ice (solid CO2) used as refrigerant. Greenhouse gas.

CO: Colourless, odourless, poisonous. Binds to haemoglobin (200x stronger than O2).

Silica and Silicates

SiO2 (Silica):

  • Found as quartz, sand, rock crystal.
  • Three-dimensional network solid.
  • Used in glass manufacture.

Silicates:

  • Basic structural unit: SiO4^4- tetrahedron.
  • Types: orthosilicates, pyrosilicates, chain, sheet, cyclic silicates.

Silicon Compounds

Silicones:

  • Organosilicon polymers. R2SiO units.
  • Water repellent, heat resistant.
  • Used as sealants, lubricants, insulators.

Sodium silicate (Na2SiO3): Water glass, used in detergents and adhesives.

Worked Examples

Example 1: Explain why BCl3 is a Lewis acid while AlCl3 is also a Lewis acid but dimerises. Solution: B in BCl3 has 6 electrons (incomplete octet), accepts electron pair (Lewis acid). Al in AlCl3 also has incomplete octet but larger size allows dimerisation to Al2Cl6 (bridging Cl atoms).

Example 2: Why is CO2 a gas while SiO2 is a solid? Solution: CO2 has discrete molecular structure (weak van der Waals forces). SiO2 has 3D network covalent bonding (very strong).

Common Mistakes

  1. Inert pair effect: Down Group 13 and 14, lower oxidation state becomes more stable (+1 for Tl, +2 for Pb).
  2. Boron is electron deficient: Forms electron-deficient compounds like B2H6 (three-centre two-electron bonds).
  3. Catenation: Carbon shows maximum catenation due to strong C-C bonds.
  4. SiO2 vs CO2: CO2 is monomeric; SiO2 is polymeric network.

ISC Exam Focus

  • Theory (70%): Group trends, boron compounds, allotropes of carbon, silicones.
  • Application (30%): Explaining properties, writing reactions, comparing elements.
  • ISC frequently asks: "Compare diamond and graphite" and "Explain inert pair effect".
  • Borax bead test and boric acid properties are commonly tested.

Self-Test Questions

Q1: Write the electronic configuration of Group 13 and Group 14 elements. Answer: Group 13: ns^2 np^1. Group 14: ns^2 np^2.

Q2: Distinguish between diamond and graphite. Answer: Diamond: sp^3, hard, insulator, tetrahedral. Graphite: sp^2, soft, conductor, layered.

Q3: What is the inert pair effect? Give an example. Answer: Tendency of ns^2 electrons to remain unshared increases down a group. Example: Tl+ is more stable than Tl3+, Pb2+ more stable than Pb4+.

Q4: Write the structure of diborane (B2H6). Answer: Banana-shaped bonds with two 3-centre-2-electron B-H-B bridge bonds and four terminal B-H bonds.

Q5: Why is boric acid a weak monobasic acid? Answer: It accepts OH- from water: B(OH)3 + H2O -> [B(OH)4]^- + H+, acting as Lewis acid.

Q6: Write two uses of silicones. Answer: As sealants, water repellents, lubricants, and electrical insulators.

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