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4CH1

Chemical Formulae, Equations and Calculations

Principles of Chemistry · 6 question types

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4CH1 Topics

States of Matter6%
Elements, Compounds and Mixtures5%
Atomic Structure9%
The Periodic Table8%
Chemical Formulae, Equations and Calculations17%
  1. Word Equations and Balanced Symbol Equations
  2. Relative Formula Mass (Mr)
  3. The Mole and Mass Conversions
  4. Reacting Masses and Percentage Yield
  5. Empirical and Molecular Formulae
  6. Concentration of Solutions
  7. Volumes of Gases at RTP
Ionic Bonding9%
Covalent Bonding8%
Metallic Bonding5%
Electrolysis7%

Frequency legend

High (≥14%)
Above avg (10 to 13%)
Average (<10%)

Exam Frequency Analysis

Past paper frequency (2018 to 2024)

This topic accounts for approximately 17% of your exam marks.

stable
Very High
Stable17%

Highest-frequency topic: moles, percentage yield and titration calculations appear on nearly every paper.

Conservation of mass

  • During a chemical reaction, atoms are rearranged but never created or destroyed
  • This is the law of conservation of mass: the total mass of reactants equals the total mass of products
  • It is why every chemical equation must be balanced

Word equations

  • A word equation uses the full chemical names of the substances involved:

reactants → products

  • The left of the arrow shows the reactants (the starting substances)
  • The right of the arrow shows the products (the new substances formed)
  • The arrow (→) is read as "produces" or "reacts to give"
  • Reaction conditions (e.g. heat, the name of a catalyst) can be written above the arrow

Example. Magnesium burns in oxygen to form magnesium oxide:

magnesium + oxygen → magnesium oxide

Symbol (chemical) equations

  • A symbol equation uses chemical formulae instead of full names
  • Three rules to remember:
    1. The diatomic non-metals must be written as molecules: H₂, N₂, O₂, F₂, Cl₂, Br₂ and I₂
    2. State symbols can be written in brackets after each formula:
      • (s) = solid
      • (l) = liquid
      • (g) = gas
      • (aq) = aqueous (dissolved in water)
    3. The equation must be balanced — the same number of each kind of atom must appear on both sides

Example (combustion of sulfur):

S (s) + O₂ (g) → SO₂ (g)

Balancing equations

  • Work across the equation from left to right, checking each element in turn
  • Adjust the coefficient (the number written in front of each formula) until the counts match on both sides
  • Never change the subscripts inside a formula — that would change what the substance is. Adding a 2 to make H₂O into H₂O₂ turns water into hydrogen peroxide
  • Treat polyatomic groups that survive the reaction unchanged (NO₃⁻, SO₄²⁻, CO₃²⁻, etc.) as single units rather than counting their individual atoms
  • Balance any element that appears on its own last

Example. Balancing the combustion of methane:

CH₄ + O₂ → CO₂ + H₂O

  1. Carbon: 1 on each side ✓
  2. Hydrogen: 4 on the left, only 2 on the right → put a 2 in front of H₂O:

CH₄ + O₂ → CO₂ + 2H₂O

  1. Oxygen: 2 on the left, now 4 on the right (2 from CO₂ + 2 from 2H₂O) → put a 2 in front of O₂:

CH₄ + 2O₂ → CO₂ + 2H₂O

  1. Re-check: C 1 = 1, H 4 = 4, O 4 = 4 ✓

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Group Reactivity and the Noble Gases

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Relative Formula Mass (Mr)