In simple terms
A friendly intro before the formal notes — no formulas yet.
Certainty, Not Just Evidence
A proof is a chain of logic so tight that the conclusion cannot be false if the starting points are true. Checking examples builds a hunch; a proof settles the matter forever. This lesson gives you three ways to build that chain.
Think of an infinite row of dominoes. Induction is the promise that they all fall: you show the first one topples (the base case) and you show that whichever one falls knocks over its neighbour (the inductive step) — so every domino, all the way to infinity, must fall. Contradiction is the opposite move: to prove a door is locked, you suppose it is open, walk through, and end up somewhere impossible — so it could never have been open. And a counterexample is the whistle-blower: one honest witness who was NOT at the library on Tuesday is enough to sink the claim that 'everyone is always at the library on Tuesdays'.
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Read the claim precisely. Is it universal ('for all ')? Is it about a property such as irrationality or infinitude? Or are you being asked to disprove something?
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Choose the technique. Universal statements over the positive integers point to induction. Properties like irrationality, or 'there are infinitely many...', point to contradiction. A 'disprove' or 'is it always true?' invites a counterexample.
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Build the argument in full. Induction needs base case, hypothesis, step and conclusion. Contradiction needs a clearly stated negation, a clean deduction, and the impossibility named. A counterexample needs the specific value and the check that it fails.
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Close the loop. Every proof ends with a sentence that connects your working back to the original statement — for induction, the formal appeal to the principle of mathematical induction.
Explore the concept
Use the live diagram and synced steps — play it or tap a step card to walk through.
Full topic notes
Formal explanation with the rigour you need for the exam.
What a proof is — and why examples are not enough
A mathematical proof is a finite chain of logically valid steps that starts from things already accepted as true (definitions, axioms, earlier results) and ends at the statement you want to establish. If the steps are valid and the starting points are true, the conclusion cannot be false. This is a far higher standard than evidence. Checking that a formula works for shows only that it works for those hundred values; a universal claim ranges over infinitely many, so no finite check can settle it. That gap is exactly why the three techniques of this lesson exist: induction to cover all positive integers in one argument, contradiction to pin down properties that resist direct attack, and the counterexample to demolish a false universal claim with a single case.
Disproof by counterexample
This is the quickest technique and it does exactly one job: it disproves. If a statement claims something holds for every value in a set, a single case where it fails — a counterexample — kills the claim. Crucially, the reverse is not true: no number of successful cases can prove a universal statement, so a counterexample can never be used to prove, only to disprove.
Proof by contradiction
To prove a statement by contradiction, you assume its negation — that it is false — and reason validly until you reach something logically impossible. Because your reasoning was sound, the only thing that can have gone wrong is the assumption, so the original statement must be true. This technique shines where a direct attack is awkward: proving a number is irrational, or that infinitely many objects exist. The set-piece example every HL student should know cold is the irrationality of .
Assume the negation. State clearly the opposite of what you must prove — this line is worth a mark.
Deduce validly. Every step from the assumption must be logically watertight; a slip here invalidates the whole proof.
Name the impossibility. Arrive at a statement that cannot be true (a lowest-terms fraction whose parts share a factor; a number both even and odd).
Conclude. State that the assumption is therefore false, so the original statement is true.
Proof by mathematical induction
Induction proves that a proposition holds for every positive integer from a starting value onward. The idea is the falling dominoes: if the first domino falls (the base case), and every fallen domino topples the next (the inductive step), then all of them fall. Formally there are four parts, and each carries marks: define , prove the base case, state the inductive hypothesis for , complete the inductive step to , and write the concluding statement. The syllabus applies this to three flavours of statement — summation formulae, divisibility results and inequalities — and the structure is identical in all three.
The proposition . State precisely what you are proving for a general ; every later line refers back to it.
Base case. Show (or the stated first value) is true. This is a separate, compulsory mark and usually the easiest one.
Inductive hypothesis. Assume is true for one arbitrary — for , not for all , and not for .
Inductive step. Using the hypothesis, prove . Work from one side of to the other; do not assume the equality.
Conclusion. Since holds and , by the principle of mathematical induction holds for all .
Common mistakes examiners penalise
Skipping or fudging the base case. It is a separate mark and the whole chain depends on it. 'Clearly true for ' with no substitution usually scores nothing — actually evaluate both sides.
Mis-stating the inductive hypothesis. Assume for one . Writing 'assume true for all ' assumes the very thing you are proving; writing 'assume for ' is circular.
Assuming the equality. Starting from the full equation and 'showing both sides are equal' is circular. Transform one side into the other using the hypothesis.
Not using the hypothesis at all. If your inductive step never invokes , it is not an inductive proof — the substitution is where the method mark lives.
Omitting the concluding statement. The formal appeal to the principle of mathematical induction is a reasoning mark; a proof with perfect algebra but no conclusion loses it.
Trying to prove with examples. Verifying a universal claim for many values is not a proof; only a general argument is. Conversely, a single counterexample fully disproves — you never need a second.
Weak contradiction set-up. In the proof you must state that is in lowest terms at the start, or the contradiction at the end has nothing to contradict.
Treating an AG proof loosely. Because the answer is given, working backwards from it or merely restating it earns nothing — every step must be shown forwards.
Model answer — marked the way our engine marks it
A proof by induction has a standard mark allocation, and our engine mirrors it exactly. Because the result is 'answer given' (AG), the marks live in the structure: method marks (M) for each required move, an accuracy mark (A) for the key algebra, and reasoning marks (R) for the valid inductive step and the concluding statement. Study how each of the six marks below attaches to a specific line — that is precisely how the Practice button will mark your own attempt.
Where this leads
The proof habits you build here recur across HL: induction reappears for de Moivre's theorem in complex numbers, for results about derivatives and sequences, and for many series identities; contradiction underlies uniqueness and irrationality arguments; and the counterexample remains your fastest tool for testing whether a tempting conjecture is actually true. More than any single result, what transfers is the discipline of the four techniques — state the proposition, cover the base case, use the hypothesis, name the impossibility, exhibit the witness, and always close the loop. Master that structure and proof questions become variations on a method you already own.
Worked examples
See the formulas applied — reveal one step at a time, like the exam.
Disprove the conjecture that is prime for every positive integer . [3]
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We need one value of for which is not prime.
Prove by contradiction that is irrational. [6]
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Assumption. Suppose, for contradiction, that is rational. [M1: assume the negation] Then for integers with , where the fraction is in lowest terms, so and have no common factor. [R1: set-up in lowest terms]
Use mathematical induction to prove that is divisible by for all . [7]
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Let be the statement ' is divisible by '.
Use mathematical induction to prove that for all integers . [7]
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Let be the statement '', for integers .
Prove by mathematical induction that for all positive integers . [6]
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Model answer — full working.
How it all connects
The big idea sits in the middle — tap a linked idea to explore the link.
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
Answer in your head first — then tap to check. No pressure.
Revision flashcards
Flip the card. Test yourself before the exam.
What are the four parts of a proof by mathematical induction?
- Base case: prove the statement is true for the first value (usually ). 2. Inductive hypothesis: assume it is true for . 3. Inductive step: use that assumption to prove it for . 4. Conclusion: appeal to the principle of mathematical induction.
Key takeaways
Review these before you close the topic — retrieval beats re-reading.
- ✓
Assume the negation. State clearly the opposite of what you must prove — this line is worth a mark.
- ✓
Deduce validly. Every step from the assumption must be logically watertight; a slip here invalidates the whole proof.
- ✓
Name the impossibility. Arrive at a statement that cannot be true (a lowest-terms fraction whose parts share a factor; a number both even and odd).
- ✓
Conclude. State that the assumption is therefore false, so the original statement is true.
Practice — then mark it
The whole point: a real Cambridge question, marked mark-by-mark.
Practise Proof Questions
Practise Proof Questions
Extra simulations & links
PhET, GeoGebra and other curated tools — open in a new tab.
Frequently asked
Checkpoint
One marked question is worth ten re-reads — close the loop before you move on.
Reading it isn’t knowing it — prove it.
Before you move on: do Practise Proof Questions on paper, snap a photo, and get examiner-style feedback on exactly where you win and lose marks.