Period 3 Oxides Exam Practice | AQA A-Level Chemistry

(a) Write balanced chemical equations for the reactions of sodium oxide and sulfur trioxide with water. State the approximate pH of the resulting solution in each case. [4]

(b) Explain why sodium oxide and phosphorus(V) oxide behave differently when added to water. Refer to their structure, bonding, and the nature of the solutions formed in your answer. [4]

Show Mark Scheme

(a)

Na₂O(s) + H₂O(l) → 2NaOH(aq) [1]; pH = 13 or 14 [1]
SO₃(g) + H₂O(l) → H₂SO₄(aq) [1]; pH = 0, 1 or 2 [1]

(b)

Sodium oxide is a giant ionic lattice containing O^2- ions [1]
The oxide ions are strongly basic and react with water to form hydroxide ions (OH^-), resulting in an alkaline solution [1]
Phosphorus(V) oxide is a simple molecular structure with covalent bonds [1]
It reacts with water to form phosphoric acid (H₃PO₄) which dissociates to release hydrogen ions (H⁺), resulting in an acidic solution [1]

Examiner tip: Ensure you relate the chemical behavior directly to the bonding. Ionic oxides contain the basic O^2- ion which reacts with water to yield OH^-. Covalent oxides react to yield acidic species that dissociate to form H⁺.

(a) Explain why the melting point of magnesium oxide is much higher than that of sodium oxide. [3]

(b) Silicon dioxide has a melting point of 1713 degrees Celsius. State its structure and bonding, and explain why its melting point is so high. [2]

(c) Explain, in terms of structure and intermolecular forces, why sulfur dioxide is a gas at room temperature. [2]

Show Mark Scheme

(a)

Both sodium oxide and magnesium oxide exist as giant ionic lattices [1]
The Mg²⁺ ion has a higher positive charge than the Na⁺ ion and is smaller [1]
This results in much stronger electrostatic forces of attraction between the Mg²⁺ and O^2- ions, requiring more energy to break the lattice [1]

(b)

Silicon dioxide has a giant covalent (macromolecular) structure [1]
Melting requires breaking many strong covalent bonds throughout the giant network, which requires a huge amount of thermal energy [1]

(c)

Sulfur dioxide exists as simple molecules [1]
It has only weak intermolecular forces (van der Waals and dipole-dipole forces) between molecules, which require very little energy to overcome [1]

Examiner tip: Be careful not to confuse covalent bonds with intermolecular forces. When melting or boiling simple molecular substances (like SO₂, SO₃, P₄O₁₀), covalent bonds are NOT broken; only the weak intermolecular forces holding the molecules together are overcome.

(a) Define the term amphoteric. [1]

(b) Write a balanced chemical equation, including state symbols, for the reaction of aluminium oxide with hydrochloric acid. [2]

(c) Write a balanced chemical equation, including state symbols, for the reaction of aluminium oxide with aqueous sodium hydroxide to form sodium tetrahydroxoaluminate. [3]

Show Mark Scheme

(a)

An oxide that can react as both an acid and a base [1]

(b)

Al₂O₃(s) + 6HCl(aq) → 2AlCl₃(aq) + 3H₂O(l)
Award [1] for correct formulas, [1] for correct state symbols.

(c)

Al₂O₃(s) + 2NaOH(aq) + 3H₂O(l) → 2NaAl(OH)₄(aq)
Award [1] for correct reactants and products, [1] for correct balancing, and [1] for correct state symbols.

Examiner tip: The reaction of aluminium oxide with NaOH is a complex ion reaction. Make sure you remember that water is a reactant: Al₂O₃ + 2NaOH + 3H₂O. The product is NaAl(OH)₄ (sodium tetrahydroxoaluminate), which is soluble in water.

3.2.4 Period 3 Oxides Exam Practice

📋 Structured Questions

Question 1: Structure and Water Reactions

Question 2: Physical Properties and Bonding

Question 3: Amphoteric Nature of Aluminium Oxide