In simple terms
A friendly intro before the formal notes — no formulas yet.
The Proton Passing Game
An acid is a substance that gives away a proton and a base is one that accepts it. That single act of passing a proton turns the original acid and base into their 'conjugate' forms, and it is the same event whether you are neutralising stomach acid, dissolving limestone or buffering blood.
Picture a dance where partners keep swapping a single hat, and the hat is the proton, . The person who starts with the hat is the acid; they hand it to their partner, the base. Once the hat has changed hands, the first person is now empty-handed and ready to receive a hat again (they have become a conjugate base), while their partner now holds the hat and could pass it on (they have become a conjugate acid). Every proton transfer reaction is just this one exchange, and it always creates two matched pairs.
- 1
Spot the reactants: one species can donate a proton (the acid, e.g. HCl) and one can accept it (the base, e.g. H₂O).
- 2
Follow the proton. The base uses a lone pair of electrons to bond the incoming .
- 3
Read off the products. The acid, having lost , becomes its conjugate base (Cl⁻); the base, having gained , becomes its conjugate acid (H₃O⁺).
- 4
Pair them up: acid with its conjugate base, base with its conjugate acid. Members of a pair differ by exactly one .
Explore the concept
Use the live diagram, PhET or GeoGebra sim, and synced steps — play it, drag controls, or tap a step.
Step 1
Spot the reactants: one species can donate a proton (the acid, e.g. HCl) and one can accept it (the base, e.g. H₂O).
Key formulas
Tap any symbol to reveal exactly what it means and its units.
Full topic notes
Formal explanation with the rigour you need for the exam.
The Brønsted-Lowry model
In 1923 Johannes Brønsted and Thomas Lowry independently proposed that acid-base behaviour is really about proton transfer. A Brønsted-Lowry acid is a species that donates a proton (); a Brønsted-Lowry base is a species that accepts a proton. A 'proton' here is a hydrogen ion — a hydrogen atom that has lost its electron. The model is not limited to water and does not require a base to contain hydroxide, which is why it explains far more than the older Arrhenius definitions.
When hydrogen chloride dissolves in water, the HCl molecule donates a proton to a water molecule, so HCl is the acid and is the base. In water the free proton is carried by a water molecule as the hydronium (oxonium) ion, .
Conjugate acid-base pairs
Because a proton is transferred, every Brønsted-Lowry reaction produces two conjugate pairs. When an acid donates its proton, what remains is its conjugate base; when a base accepts a proton, the species formed is its conjugate acid. The two members of a pair always differ by exactly one , so their formulae differ by one H and their charges differ by one unit.
A conjugate acid-base pair differs by a single proton (): one more H and a charge one unit more positive on the acid side.
Acid (donates ) conjugate base.
Base (accepts ) conjugate acid.
In the pairs are and .
Amphiprotic species
Some species can act as either a Brønsted-Lowry acid or a base, depending on their reaction partner. These are amphiprotic. To behave this way a species needs both a hydrogen atom it can donate and a lone pair with which to accept a proton. Water is the classic case: it donates a proton to become , or accepts one to become . The hydrogencarbonate ion, , is another key example, along with and .
Water: donates to become ; accepts to become .
Hydrogencarbonate, : donates to give ; accepts to give .
Take care with vocabulary: 'amphiprotic' specifically means donating/accepting protons (Brønsted-Lowry). 'Amphoteric' is broader — any acid or base behaviour, including Lewis. All amphiprotic species are amphoteric, but not the reverse (e.g. is amphoteric but not amphiprotic).
A favourite exam task is to write two equations showing an amphiprotic species acting as an acid in one and a base in the other. Choose the partners deliberately: to make it act as an ACID, react it with a base (e.g. ); to make it act as a BASE, react it with an acid (e.g. or a stronger acid). Balance charges to check you have the right conjugate.
The pH scale and hydrogen ion concentration
Hydrogen ion concentrations in solution span an enormous range, so we compress them onto a logarithmic scale: , where is in mol dm⁻³. Rearranged, . The key feature is that the scale is logarithmic, so each whole pH unit corresponds to a TEN-FOLD change in : a solution of pH 2 has ten times the hydrogen ion concentration of one at pH 3, and a hundred times that of one at pH 4. A lower pH means a higher and a more acidic solution.
pH falls as rises — the minus sign in the definition flips the direction.
One pH unit = a ten-fold change in ; the scale is logarithmic, not linear.
At 298 K, pH < 7 is acidic, pH = 7 is neutral, pH > 7 is basic.
(HL) and, at 298 K, .
Strong and weak acids and bases
'Strong' and 'weak' describe the EXTENT to which an acid or base reacts with water — nothing to do with how concentrated it is. A strong acid dissociates essentially completely: in HCl(aq) virtually every molecule has donated its proton, so we write a single arrow. A weak acid only partially dissociates and reaches an equilibrium, so we write a reversible arrow and most of it remains as intact molecules. The same distinction applies to bases: a strong base such as NaOH is fully dissociated into ions, whereas a weak base such as NH₃ is only partially protonated at equilibrium.
This is why, at the SAME concentration, a strong acid has a higher and therefore a LOWER pH than a weak acid: the strong acid has released far more of its available protons. It is also why 'strong' and 'concentrated' must never be swapped — you can have a dilute strong acid (low concentration, fully dissociated) or a concentrated weak acid (high concentration, barely dissociated).
If a question asks you to compare a strong and a weak acid, always anchor your answer to EXTENT of dissociation: the strong acid dissociates completely, the weak acid only partially, so the strong acid has the higher [H⁺] and lower pH at equal concentration. Never explain the difference using the word 'concentrated'.
Characteristic reactions of acids
Acids show three signature reactions you must be able to write and recognise. Each is a proton transfer, and each has an observation you can quote in the exam.
Neutralisation is the exact cancellation of an acid by a base: hydrogen ions from the acid combine with hydroxide ions (or another base) to form water, and the remaining ions form the salt. Because the underlying reaction is always , neutralisation of any strong acid by any strong alkali releases the same enthalpy change per mole of water formed.
Acid + reactive metal → salt + hydrogen. e.g. . Observation: effervescence; the gas gives a 'squeaky pop' with a lit splint.
Acid + base or alkali → salt + water (neutralisation). e.g. . The net ionic equation is simply .
Acid + carbonate (or hydrogencarbonate) → salt + water + carbon dioxide. e.g. . Observation: effervescence; the CO₂ turns limewater milky.
HL extension: Ka, Kb, pKa, pKb, pH calculations and buffers
At HL the strong/weak distinction is made quantitative. For a weak acid , the acid dissociation constant is ; a larger means more dissociation and a stronger acid. For a weak base the equivalent is . Because these constants span many orders of magnitude, we usually quote and . Watch the direction: the stronger the acid, the LARGER its but the SMALLER its . For a conjugate acid-base pair at 298 K, .
(HL) ; larger (smaller ) = stronger acid.
(HL) and ; for a conjugate pair at 298 K.
(HL) Strong acid pH: equals the acid concentration, so directly.
(HL) A buffer resists pH change and is made of a weak acid plus its conjugate base (e.g. /) or a weak base plus its conjugate acid. Added is removed by the conjugate base and added is removed by the weak acid, so the pH barely moves.
Common mistakes examiners penalise
Confusing 'strong' with 'concentrated' — strong/weak is about extent of dissociation; concentrated/dilute is about amount per volume. They are independent, and swapping them loses the mark outright.
Writing a conjugate pair that differs by more than one H⁺ — a conjugate pair differs by exactly one proton, so / is NOT a pair, but / and / are.
Getting the charge wrong on a conjugate — accepting raises the charge by +1, donating lowers it by 1. Check the charge as well as the H count.
Treating pH as linear — a change of 2 pH units is a factor of 100 in , not 'twice as acidic'.
Dropping the minus sign in pH = −log[H⁺] — forgetting it gives a negative pH for an acidic solution, which should immediately look wrong.
Saying a weak acid 'does not ionise' — it partially ionises and sits at equilibrium; use a reversible arrow, not 'no reaction'.
Wrong products for acid + carbonate — it gives salt + water + CO₂ (three products), not salt + hydrogen.
(HL) Reversing the Ka/pKa direction — a STRONGER acid has a LARGER Ka but a SMALLER pKa.
Model answer — marked the way our engine marks it
Acid-base questions on Paper 2 mix a short calculation with a worded explanation, and the marks are analytic: each is tied to a specific line of working (a method mark, M, or an answer mark, A), while error-carried-forward (ECF) means a wrong number early on need not cost every later mark. The explanation marks are awarded for distinct, correct points — you earn them one idea at a time. Study how each mark below is won.
Where this leads
Proton transfer is the foundation for everything that follows in acid-base chemistry. Titration curves are just pH plotted as one solution neutralises another; the sharp jump at the equivalence point is a large change in shown on the logarithmic pH scale. At HL, and turn the strong/weak idea into calculations of pH for weak acids, and buffers apply Le Châtelier's principle to a conjugate pair. Master the two habits here — track the single proton, and reason from extent of dissociation rather than concentration — and the rest of the topic becomes variations on ideas you already own.
Worked examples
See the formulas applied — reveal one step at a time, like the exam.
For the reaction , identify the Brønsted-Lowry acid, base, conjugate acid and conjugate base, and state the two conjugate pairs. [4]
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Step 1 — follow the protons. : it has gained an H and its charge has risen by +1, so it has ACCEPTED a proton. : it has lost an H and its charge has fallen by 1, so it has DONATED a proton.
A strong acid has mol dm⁻³. (a) Calculate its pH. (b) Explain the difference between a strong and a weak acid of the same concentration. [4]
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Model answer — full working.
How it all connects
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Tap a linked idea to see how it connects back to the main topic — that connection is what examiners reward.
Glossary
Try to recall each definition before you reveal it.
Quick check
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Revision flashcards
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Brønsted-Lowry acid
A proton () donor. It does not need to contain oxygen, and the definition is not limited to aqueous solution.
Key takeaways
Review these before you close the topic — retrieval beats re-reading.
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A conjugate acid-base pair differs by a single proton (): one more H and a charge one unit more positive on the acid side.
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Acid (donates ) conjugate base.
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Base (accepts ) conjugate acid.
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In the pairs are and .
Practice — then mark it
The whole point: a real Cambridge question, marked mark-by-mark.
Get a Paper 2 acid-base question marked: calculate a pH and explain strong vs weak with full working
Get a Paper 2 acid-base question marked: calculate a pH and explain strong vs weak with full working
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Checkpoint
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Reading it isn’t knowing it — prove it.
Before you move on: do Get a Paper 2 acid-base question marked: calculate a pH and explain strong vs weak with full working on paper, snap a photo, and get examiner-style feedback on exactly where you win and lose marks.