Ib chemistry – structure 2

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IB Chemistry: Structure 2 Mastery Booklet
IB Chemistry Course Companion

STRUCTURE 2

Models of Bonding

IONIC • COVALENT • METALLIC • VSEPR • ALLOYS

CORE

2.1 The Ionic Model

Guiding Principle: Ionic bonding is not just electron transfer; it is the electrostatic stability of a giant crystal lattice.

1. The Ionic Bond

Definition: The electrostatic attraction between oppositely charged ions (cations and anions).

Formation: Occurs when electronegativity difference ($\Delta\chi$) is > 1.8. (Metal loses $e^-$, Non-metal gains $e^-$).

2. The Lattice Structure

Ionic compounds do not exist as discrete molecules. They form a Giant Ionic Lattice—a continuous 3D repeating pattern.

3. Physical Properties (How to argue for marks)

Melting/Boiling Points: High

Large energy required to overcome strong electrostatic forces holding the lattice together.

Electrical Conductivity

Solid: No (Ions are fixed in position).
Molten/Aqueous: Yes (Lattice broken, ions free to move).

Trap Alert

Never say "electrons move" in ionic conduction. In ionic compounds, ions carry the charge.

Brittleness

Force causes layers to slide. Ions of same charge align. Massive repulsion shatters the crystal.

CORE

2.2 The Covalent Model

Guiding Principle: Atoms share electrons to achieve a full valence shell because neither atom is strong enough to take electrons from the other.

1. The Covalent Bond

Definition: The electrostatic attraction between a shared pair of electrons and the positively charged nuclei.

Coordinate (Dative) Bonds: A bond where both electrons in the shared pair originate from the same atom (e.g., $NH_4^+$).

Examiner Tip

When drawing Lewis structures for ions (e.g., $NH_4^+$), you must place the entire structure in square brackets $[ ... ]^+$ with the charge outside.

2. VSEPR Theory (Molecular Geometry)

Valence Shell Electron Pair Repulsion: Domains repel to be as far apart as possible.

Repulsion Hierarchy: Lone Pair-Lone Pair > Lone Pair-Bonding Pair > Bonding Pair-Bonding Pair.

Domains Bonding Lone Shape Name Angle Example
220Linear$180^\circ$$CO_2$
330Trigonal Planar$120^\circ$$BF_3$
321Bent (V-shaped)$<120^\circ$$SO_2$
440Tetrahedral$109.5^\circ$$CH_4$
431Trigonal Pyramidal$107^\circ$$NH_3$
422Bent (V-shaped)$104.5^\circ$$H_2O$

3. Polarity & Intermolecular Forces

London (Dispersion) Forces (LDF) Weakest. Present in ALL molecules. Caused by temporary dipoles. Strength increases with molar mass (more electrons).
Dipole-Dipole Forces Attraction between permanent dipoles in polar molecules.
Hydrogen Bonding Strongest IMF. Occurs when H is bonded directly to F, O, or N.
⚠️ Trap Alert: A Hydrogen Bond is an attraction BETWEEN molecules, not inside them.

4. Giant Covalent Structures

Diamond (C)

Tetrahedral. Hard. No conduction (no free electrons).

Graphite (C)

Hexagonal layers. Conducts (delocalized electron). Soft (layers slide).

CORE

2.3 & 2.4 Metallic Model

1. Metallic Bonding

Definition: The electrostatic attraction between a lattice of positive metal ions (cations) and a sea of delocalized electrons.

  • Conductivity: Delocalized electrons move freely to carry current.
  • Malleability: Non-directional bonding allows layers to slide without breaking.

2. Alloys (Materials)

Definition: Homogeneous mixtures of metals (e.g., Brass, Steel).

Why are alloys harder? Different sized atoms distort the lattice, preventing layers from sliding over each other.

⛔️ STOP HERE IF YOU ARE SL

Advanced Theory

The following section is for HL Students ONLY.

AHL

Advanced Covalent Bonding

1. Formal Charge (The Tie-Breaker)

When multiple valid Lewis structures exist, Formal Charge (FC) determines the stable one.

$$FC = (\text{Valence } e^-) - (\text{Non-bonding } e^-) - \frac{1}{2}(\text{Bonding } e^-)$$
  • Choose the structure where FCs are closest to zero.
  • If charges exist, negative FC must be on the most electronegative atom.

2. Resonance, Sigma ($\sigma$) & Pi ($\pi$) Bonds

Resonance: Occurs when a double bond can be in multiple positions (e.g., Benzene). The true structure is a hybrid (average).

Sigma ($\sigma$) Bond

Head-on overlap. $e^-$ density between nuclei. Stronger.

Pi ($\pi$) Bond

Sideways overlap. $e^-$ density above/below plane. Weaker.

Single = 1$\sigma$ | Double = 1$\sigma$ + 1$\pi$ | Triple = 1$\sigma$ + 2$\pi$

3. Hybridization ($sp, sp^2, sp^3$)

Atoms mix orbitals to create new "hybrid" orbitals of equal energy.

Domains Hybridization Geometry Example
4$sp^3$TetrahedralMethane ($CH_4$)
3$sp^2$Trigonal PlanarEthene ($C_2H_4$)
2$sp$LinearEthyne ($C_2H_2$)

4. Expanded Octets

Period 3+ elements (P, S, Cl) use d-orbitals to hold >8 electrons.

Domains Lone Shape Angles Ex
50Trigonal Bipyramidal90, 120, 180$PCl_5$
51Seesaw<90, <120$SF_4$
52T-shaped<90$ClF_3$
53Linear180$I_3^-$
60Octahedral90, 180$SF_6$
62Square Planar90$XeF_4$

The Examiner's Vault

Strictly assessed on Structure 2 content.

1. Which compound has the highest lattice enthalpy? IONIC
A. $NaCl$
B. $KCl$
C. $MgO$
D. $CaO$
2. What is the shape of the $I_3^-$ ion? VSEPR
A. Linear
B. Bent
C. Trigonal Planar
D. Trigonal Bipyramidal
HL
3. What is the hybridization of Nitrogen in $NO_3^-$?
A. $sp$
B. $sp^2$
C. $sp^3$
D. $dsp^3$
4. Diamond vs Graphite (Core)

Explain why Graphite is used as a lubricant, whereas Diamond is used in cutting tools.

HL
5. Bonding Analysis: Propyne ($CH_3-C\equiv C-H$)

(a) Deduce the number of sigma ($\sigma$) and pi ($\pi$) bonds.
(b) Identify the hybridization of the central carbon atom.

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