In simple terms
A friendly intro before the formal notes — no formulas yet.
Cooking from a Molecular Recipe
A balanced equation tells you the exact ratio in which substances react — but that ratio is counted in moles, not grams. Stoichiometry is the habit of always converting to moles, crossing the mole ratio, and converting back to whatever the question wants.
A pancake recipe reads '1 egg + 2 cups flour → 6 pancakes'. If you have 3 eggs and only 2 cups of flour, you cannot make 18 pancakes — the flour runs out first. The flour is your limiting ingredient, and it alone sets how many pancakes you get. And if the recipe promises 6 pancakes but you burn one, your yield is only 5 out of 6. Chemical reactions work the same way, except the recipe ratio is counted in moles.
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Write a balanced equation — its coefficients are the mole ratio, the only reliable link between substances.
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Convert what you are given into moles: for a mass, for a solution, or for a gas.
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If two reactant amounts are given, find the limiting reactant by dividing each amount by its coefficient — the smallest value limits.
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Cross the mole ratio to the target substance, then convert back to a mass, a volume, a concentration or a yield.
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Full topic notes
Formal explanation with the rigour you need for the exam.
Mole ratios and reacting masses
A balanced equation is a recipe written in moles. Its coefficients give the mole ratio — the ratio in which substances react and form — and this ratio is the heart of every stoichiometry calculation. The one rule that never bends is that the ratio applies to MOLES, never directly to masses. So the reliable route is always the same three moves: convert the known mass to moles with , cross the mole ratio to the substance you want, then convert back to a mass with .
Convert the known mass to moles: (divide, never multiply).
Cross the mole ratio from the balanced equation to reach the target substance.
Convert back to a mass, a volume, a number of particles or a concentration.
Mass is conserved: total mass of reactants equals total mass of products — a quick sanity check.
Gas volumes: the molar gas volume and Avogadro's law
When a substance is a gas, you often measure its volume rather than its mass. Two ideas make this easy. First, the molar gas volume is the volume occupied by one mole of any ideal gas at a stated temperature and pressure; at STP (0 °C and 100 kPa) it is dm³ mol⁻¹, so . Second, Avogadro's law states that equal volumes of gases at the same temperature and pressure contain equal numbers of moles. The powerful consequence is that for reacting GASES the volume ratio equals the mole ratio directly — you can work in volumes without ever converting to moles.
For example, in the complete combustion of methane, CH₄(g) + 2O₂(g) → CO₂(g) + 2H₂O(l), 100 cm³ of methane reacts with exactly 200 cm³ of oxygen and produces 100 cm³ of carbon dioxide (all measured at the same temperature and pressure), simply because the gas coefficients are 1 : 2 : 1. The liquid water is not counted — Avogadro's law is about gases only.
For a single gas: convert between volume and moles with .
For reacting gases (Avogadro's law): the ratio of gas volumes equals the ratio of coefficients — use volumes directly.
The molar gas volume only applies to GASES, and only at the temperature and pressure it is quoted for.
Watch units: is in dm³ mol⁻¹, so a volume in cm³ must be divided by 1000 first.
Solution stoichiometry and titrations
For reactions in solution, amount is measured through concentration and volume rather than mass. Molar concentration is the amount of solute per unit volume of solution, , in mol dm⁻³. Rearranged as , it is the door into every titration calculation. A titration reacts a measured volume of one solution with a solution of known concentration until the reaction is exactly complete (the equivalence point, usually shown by an indicator). Because you know the concentration and volume on one side, you can find the moles there, cross the mole ratio, and then find the unknown concentration on the other side.
The single most common mark lost in titration questions is the volume unit. Concentration is per dm³, but burettes and pipettes read in cm³. Convert EVERY volume from cm³ to dm³ by dividing by 1000 before it goes into . If your concentration comes out a factor of 1000 too big or too small, this is almost always the cause.
Limiting and excess reactants
In real reactions the reactants are rarely mixed in the exact stoichiometric ratio. The reactant that runs out first is the limiting reactant, and it alone controls how much product forms; whatever is left over is the excess reactant and plays no further part. The reliable test is to convert each reactant to moles and divide by its coefficient in the balanced equation — the smallest value is limiting. Do not simply pick the reactant with the smallest mass or even the smallest number of moles; the coefficients decide.
Convert every reactant to moles.
Divide each amount by its coefficient in the balanced equation.
The smallest of those values marks the limiting reactant.
Base ALL product and yield calculations on the limiting reactant; the excess is left over and irrelevant to the amount of product.
Theoretical yield, percentage yield and atom economy
The theoretical yield is the maximum product predicted by stoichiometry from the limiting reactant, assuming the reaction goes to completion with no losses. In a real lab the actual yield you collect is usually lower, so the percentage yield measures how well the reaction ran: , comparing like with like (both in moles, or both as mass of the same substance). Atom economy is a different idea — it is a design measure of how much of the reactant mass ends up in the useful product: . A reaction can have a high yield but poor atom economy if it also produces a lot of unwanted by-product. Yield describes one particular run; atom economy is fixed by the equation itself.
Common mistakes examiners penalise
Forgetting to convert cm³ to dm³ — concentration is per dm³, so divide a volume in cm³ by 1000 before using . This single slip scales the answer by 1000.
Applying the mole ratio to masses or solution volumes — coefficients relate MOLES only. Convert to moles first, then cross the ratio. (Gas volumes are the one exception, via Avogadro's law.)
Ignoring the coefficient when finding the limiting reactant — divide each reactant's moles by its coefficient; the smallest value limits. The reactant with the smallest mass or fewest moles is not automatically limiting.
Basing the yield on the excess reactant — always calculate the theoretical yield from the LIMITING reactant; the excess is left over and irrelevant.
Multiplying instead of dividing by molar mass — moles = mass ÷ , never mass × .
Confusing percentage yield with atom economy — yield measures how much product THIS reaction actually made; atom economy measures how much reactant mass the equation directs to the wanted product. They are not the same and are usually different numbers.
Losing significant figures or units — quote the final answer to the significant figures of the data (usually 3) and always give the unit; a bare number can forfeit the answer mark.
Model answer — marked the way our engine marks it
This is the showcase for a calculation topic. In Paper 2 the marks are analytic: each is tied to a specific line of working (a method mark, M, or an answer mark, A) and — crucially — the method marks and error-carried-forward (ECF) mean a wrong number early on does not cost you every mark that follows. That protection only exists if your method is written down. Study how each of these three marks is earned by a specific line.
Where this leads
Every quantitative topic ahead is a variation on these moves. Back-titrations and redox titrations reuse across more than one mole ratio; gas-law problems replace the molar gas volume with the ideal gas equation when conditions are non-standard; thermochemistry and rates multiply moles by an energy change or a rate constant. Master the three-move habit — convert to moles, cross the mole ratio, convert back — plus the limiting-reactant test, and the rest of the quantitative course becomes familiar ground.
Worked examples
See the formulas applied — reveal one step at a time, like the exam.
Calcium carbonate decomposes on heating: CaCO₃(s) → CaO(s) + CO₂(g). Calculate the mass of calcium oxide, CaO, produced when 25.0 g of calcium carbonate is fully decomposed. [3]
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Step 1 — moles of the given substance (CaCO₃). From the data booklet: , , . g mol⁻¹. mol. [M1: correct molar mass and moles]
In a titration, 25.0 cm³ of sulfuric acid is exactly neutralised by 30.0 cm³ of 0.200 mol dm⁻³ sodium hydroxide. The equation is H₂SO₄(aq) + 2NaOH(aq) → Na₂SO₄(aq) + 2H₂O(l). Calculate the concentration of the sulfuric acid. [3]
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Step 1 — moles of the known solution (NaOH). Convert the volume to dm³: . mol. [M1]
Ammonia is made by the Haber process: N₂(g) + 3H₂(g) → 2NH₃(g). In a reaction, 28.0 g of nitrogen is mixed with 9.00 g of hydrogen, and 20.0 g of ammonia is collected. (a) Identify the limiting reactant. (b) Calculate the theoretical yield of ammonia and the percentage yield. [5]
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Step 1 — moles of each reactant. g mol⁻¹, so mol. g mol⁻¹, so mol. [M1: both amounts]
25.0 cm³ of sodium hydroxide solution was exactly neutralised by 20.0 cm³ of 0.100 mol dm⁻³ hydrochloric acid. The equation is NaOH(aq) + HCl(aq) → NaCl(aq) + H₂O(l). Calculate the concentration of the sodium hydroxide solution. [3]
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Model answer — full working.
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Glossary
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Quick check
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Revision flashcards
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Mole ratio (stoichiometric ratio)
The ratio of coefficients in the balanced equation. It links MOLES of one substance to moles of another — it never applies directly to masses or volumes of liquids.
Key takeaways
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Convert the known mass to moles: (divide, never multiply).
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Cross the mole ratio from the balanced equation to reach the target substance.
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Convert back to a mass, a volume, a number of particles or a concentration.
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Mass is conserved: total mass of reactants equals total mass of products — a quick sanity check.
Practice — then mark it
The whole point: a real Cambridge question, marked mark-by-mark.
Get a Paper 2 calculation marked: work a titration or limiting-reactant problem with full working
Get a Paper 2 calculation marked: work a titration or limiting-reactant problem with full working
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Frequently asked
Checkpoint
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Before you move on: do Get a Paper 2 calculation marked: work a titration or limiting-reactant problem with full working on paper, snap a photo, and get examiner-style feedback on exactly where you win and lose marks.