Back to Unit
High Yield Topic

Chemical Bonding

Chemistry Unit 4
30 min read
IAT Advanced
High Priority

1. Core Concept

Chemical bonding is the physical process responsible for the attractive interactions between atoms and molecules, which confers stability to diatomic and polyatomic chemical compounds. Atoms bond to achieve a lower potential energy and a stable octet (noble gas configuration).

2. Kössel-Lewis Approach

Kössel and Lewis provided the first logical explanation for valence: atoms bond to complete their valence shell octet.

  • Octet Rule: Atoms gain, lose, or share electrons to reach 8 electrons in their outer shell.
  • Lewis Symbols: Represented by valence electrons as dots around the element symbol.
Formal Charge (F.C.) = V - L - ½S
V = Valence e-, L = Lone pair e-, S = Shared/Bonded e-. Helps identify the most stable Lewis structure (lowest net F.C.).

Octet Rule Limitations:

  • Incomplete Octet: LiCl, BeH2, BF3 (central atom < 8e-).
  • Expanded Octet: PCl5, SF6, H2SO4 (central atom > 8e- due to d-orbitals).
  • Odd-electron molecules: NO, NO2.

3. Ionic or Electrovalent Bond

Formed by complete transfer of electrons from a metal (low IE) to a non-metal (high ΔegH). Resulting ions are held by electrostatic force.

Factors favoring Ionic Bond:

  • Low Ionization Enthalpy of cation.
  • High magnitude of Electron Gain Enthalpy of anion.
  • High Lattice Enthalpy: The energy released when 1 mole of ionic crystal is formed from gaseous ions. (Lattice Energy ∝ Charge / Radius).

Fajan's Rule (Covalent character in Ionic bonds):

No bond is 100% ionic. Covalent character increases when:

  • Small cation (high polarizing power).
  • Large anion (high polarisability).
  • High charges on ions.
  • Cations with pseudo-noble gas configuration (ns2np6nd10, e.g., Cu+).

4. Bond Parameters

Parameter Definition / Dependency
Bond Length Equilibrium distance between nuclei. Decreases with higher B.O.
Bond Angle Angle between orbitals containing bonding pairs.
Bond Enthalpy Energy to break 1 mole of bonds. Bond Strength ∝ B.Enthalpy.
Bond Order Number of bonds between atoms. B.O. = 1 (single), 2 (double), 3 (triple).

Resonance:

When a single Lewis structure can't explain all properties (e.g., O3, CO32-). Resonance hybrids have intermediate bond lengths and lower energy.

μ = Q × r
Dipole Moment: Vector quantity measured in Debye (D). μ = 0 for symmetric molecules (e.g., BF3, CCl4); μ ≠ 0 for polar molecules (e.g., H2O, NF3).

5. VSEPR Theory

Predicts geometry based on repulsion: LP-LP > LP-BP > BP-BP.

Type BP LP Shape Example
AX2 2 0 Linear BeCl2
AX3 3 0 Trigonal Planar BF3
AX2E 2 1 Bent / V-shape SO2, O3
AX4 4 0 Tetrahedral CH4
AX3E 3 1 Trigonal Pyramidal NH3
AX2E2 2 2 Bent / V-shape H2O
AX5 5 0 Trigonal Bipyramidal PCl5
AX4E 4 1 See-saw SF4
AX3E2 3 2 T-shape ClF3
AX6 6 0 Octahedral SF6
AX5E 5 1 Square Pyramidal BrF5
AX4E2 4 2 Square Planar XeF4

6. Valence Bond Theory & Hybridisation

VBT: Bond is formed by overlap of half-filled atomic orbitals. Focuses on directional nature.

  • Sigma (σ) bond: Head-on overlap (strong).
  • Pi (π) bond: Sideways overlap (weak; only possible if σ is already present).

Hybridisation Types & Geometry:

  • sp: Linear (180°). BeCl2, C2H2.
  • sp2: Trigonal Planar (120°). BF3, C2H4.
  • sp3: Tetrahedral (109.5°). CH4, NH3, H2O.
  • sp3d: Trigonal Bipyramidal. PCl5.
  • sp3d2: Octahedral. SF6.
  • sp3d3: Pentagonal Bipyramidal. IF7.

7. Molecular Orbital Theory (MOT)

Atomic orbitals combine to form Molecular Orbitals (MO). Number of MO = Number of AO.

  • Bonding MO: Lower energy, higher stability. (σ, π).
  • Antibonding MO: Higher energy, lower stability. (σ*, π*).
Bond Order (B.O.) = ½(Nb - Na)
If B.O. > 0, species is stable. Stability ∝ B.O. Magnetic nature: Unpaired e- → Paramagnetic; All paired → Diamagnetic.

Energy Sequence (MUST KNOW):

  • Up to N2 (Z ≤ 14): σ1s < σ*1s < σ2s < σ*2s < (π2p x = π2py) < σ2pz < (π*2px = π*2py) < σ*2pz.
  • O2 and F2 (Z > 14): σ1s < σ*1s < σ2s < σ*2s < σ2pz < (π2px = π2py) < (π*2px = π*2py) < σ*2pz.

Note: The position of σ2pz changes due to s-p mixing in lighter elements.

8. Hydrogen Bonding

Special dipole-dipole interaction between H (bonded to F, O, N) and another electronegative atom.

  • Intermolecular: Between different molecules. Increases B.P. (e.g., H2O, HF, alcohols).
  • Intramolecular: Within the same molecule. Reduces B.P., increases volatility. (e.g., o-nitrophenol, Salicylaldehyde).

Density Anomaly: Ice is less dense than water because H-bonding forms a cage-like structure in solid state, increasing volume.

9. Common Mistakes

  • Dipole Moment vectors: Don't forget that in NF3, lone pair dipole opposes F dipoles, making it less polar than NH3 where they reinforce.
  • See-saw positioning: In sp3d hybridisation with 1 LP (SF4), the lone pair always occupies the equatorial position to minimize repulsion.
  • Magnetic nature of O2: Standard Lewis octet theory fails; MOT correctly predicts it as paramagnetic (2 unpaired e- in π* orbitals).

10. IAT Exam Focus Points

  • Bond Order Comparison: Arrange O2, O2+, O2-, O22-. B.O.: 2, 2.5, 1.5, 1. Stability: O2+ > O2 > O2- > O22-.
  • Isoelectronic Species Shapes: Species like CO2, BeCl2, N3- are all linear. CH4, BH4-, NH4+ are all tetrahedral.
  • Born-Haber Cycle: Understand the summation of energies (Sublimation + IE + Dissociation + EA + Lattice = Heat of Formation).
  • Bond Angles in H2O and NH3: 104.5° and 107°. Lower than 109.5° due to LP repulsion.

11. Practice Mock Test

Ready to test your knowledge?

Take a quick 15-question assessment specifically designed for Chemical Bonding. Challenge yourself with IAT-level questions.

Start Practice Mock

End of Chapter

Chemical Bonding and Molecular Structure

Contents