Algebraic proof | AQA GCSE Maths Notes

Visual model

Proof shows something is always true

2n

even

2n+1

oddrepresent every possible case

Gold-standard guide

26 mins

What you will learn

Use algebra to show that a statement is always true.

Use a clear step-by-step method for algebraic proof.

Check your answer and avoid the most common exam mistake.

Useful before you start

Core number skillsEarlier algebra skillsShowing clear working

Core knowledge

Know the rule, then use it

These are the short notes. Read each one, then check you can use it in the worked example below.

Method

In algebraic proof: represent general cases using algebra (2n for even, 2n+1 for odd, 3n for multiples of 3)

Step 1

Represent two consecutive even numbers

Let them be 2n and 2n + 2, where n is any integer

Step 2

Multiply them out

2n(2n + 2) = 4n(n + 1)

Step 3

Use the fact that one of n or n+1 must be even

Either n or n + 1 is even, so n(n + 1) is always even

Watch out

Students use specific numbers as proof (for example '2 × 4 = 8')

Core method

In algebraic proof: represent general cases using algebra (2n for even, 2n+1 for odd, 3n for multiples of 3)

Exam check

Students use specific numbers as proof (for example '2 × 4 = 8')

Worked example

Prove that the product of any two consecutive even numbers is divisible by 8.

Represent two consecutive even numbers: Let them be 2n and 2n + 2, where n is any integer.

Multiply them out: 2n(2n + 2) = 4n(n + 1).

Use the fact that one of n or n+1 must be even: Either n or n + 1 is even, so n(n + 1) is always even.Write n(n + 1) = 2k.

Conclude divisibility by 8: Product = 4 × 2k = 8k, which is a multiple of 8.∴ The product of any two consecutive even numbers is divisible by 8.

Final answer

Product = 8k for some integer k, so divisible by 8

Question ladder

Build up to the hardest questions

Do them in order. If you miss a step, read the solution, then redo the question without looking.

Workedreasoning

Prove that the product of any two consecutive even numbers is divisible by 8.

4 marks4 minsalgebraic-proof-worked

Show solution

Worked solution

1.Represent two consecutive even numbers: Let them be 2n and 2n + 2, where n is any integer.
2.Multiply them out: 2n(2n + 2) = 4n(n + 1).
3.Use the fact that one of n or n+1 must be even: Either n or n + 1 is even, so n(n + 1) is always even.Write n(n + 1) = 2k.
4.Conclude divisibility by 8: Product = 4 × 2k = 8k, which is a multiple of 8.∴ The product of any two consecutive even numbers is divisible by 8.

Final answer

Product = 8k for some integer k, so divisible by 8

Mark points

M1: represent two consecutive even numbers
M1: multiply them out
M1: use the fact that one of n or n+1 must be even
M1: conclude divisibility by 8
A1: Product = 8k for some integer k, so divisible by 8

Watch out

g. '2 × 4 = 8'). This only shows one case, not all cases. Every step must use the general algebraic form.The conclusion must quote the original claim.

Diagnosticrecall

Prove that the sum of any three consecutive integers is divisible by 3.

1 mark2 minsalgebraic-proof-q1

Show solution

Worked solution

1.Spot the skill: In algebraic proof: represent general cases using algebra (2n for even, 2n+1 for odd, 3n for multiples of 3).
2.Use the represent two consecutive even numbers stage first, then multiply them out.
3.Keep the final answer visible: n + (n+1) + (n+2) = 3n + 3 = 3(n+1), divisible by 3.

Final answer

n + (n+1) + (n+2) = 3n + 3 = 3(n+1), divisible by 3

Mark points

M1: use the correct in algebraic proof: represent general cases using algebra (2n for even, 2n+1 for odd, 3n for multiples of 3).expand and simplify, then draw a clear conclusion. never use specific numbers — that is verification, not proof.
A1: n + (n+1) + (n+2) = 3n + 3 = 3(n+1), divisible by 3

Watch out

g. '2 × 4 = 8'). This only shows one case, not all cases. Every step must use the general algebraic form.The conclusion must quote the original claim.

Easyprocedure

Prove that the sum of a number and its square is always even.

2 marks3 minsalgebraic-proof-q2

Show solution

Worked solution

1.Spot the skill: In algebraic proof: represent general cases using algebra (2n for even, 2n+1 for odd, 3n for multiples of 3).
2.Use the multiply them out stage first, then use the fact that one of n or n+1 must be even.
3.Keep the final answer visible: n + n² = n(n + 1); one of n or n+1 is even, so product is even.

Final answer

n + n² = n(n + 1); one of n or n+1 is even, so product is even

Mark points

M1: use the correct in algebraic proof: represent general cases using algebra (2n for even, 2n+1 for odd, 3n for multiples of 3).expand and simplify, then draw a clear conclusion. never use specific numbers — that is verification, not proof.
A1: n + n² = n(n + 1); one of n or n+1 is even, so product is even

Watch out

g. '2 × 4 = 8'). This only shows one case, not all cases. Every step must use the general algebraic form.The conclusion must quote the original claim.

Mediumreasoning

Disprove: 'All prime numbers are odd.'

3 marks4 minsalgebraic-proof-q3

Show solution

Worked solution

1.Spot the skill: In algebraic proof: represent general cases using algebra (2n for even, 2n+1 for odd, 3n for multiples of 3).
2.Use the use the fact that one of n or n+1 must be even stage first, then conclude divisibility by 8.
3.Keep the final answer visible: 2 is prime and even — counterexample disproves the claim.

Final answer

2 is prime and even — counterexample disproves the claim

Mark points

M1: use the correct in algebraic proof: represent general cases using algebra (2n for even, 2n+1 for odd, 3n for multiples of 3).expand and simplify, then draw a clear conclusion. never use specific numbers — that is verification, not proof.
A1: 2 is prime and even — counterexample disproves the claim

Watch out

g. '2 × 4 = 8'). This only shows one case, not all cases. Every step must use the general algebraic form.The conclusion must quote the original claim.

Hardproblem solving

Prove that (2n + 1)² − 1 is always a multiple of 8.

3 marks5 minsalgebraic-proof-q4

Show solution

Worked solution

1.Spot the skill: In algebraic proof: represent general cases using algebra (2n for even, 2n+1 for odd, 3n for multiples of 3).
2.Use the conclude divisibility by 8 stage first, then represent two consecutive even numbers.
3.Keep the final answer visible: 4n² + 4n = 4n(n+1); n(n+1) is even so 4n(n+1) = 8k.

Final answer

4n² + 4n = 4n(n+1); n(n+1) is even so 4n(n+1) = 8k

Mark points

M1: use the correct in algebraic proof: represent general cases using algebra (2n for even, 2n+1 for odd, 3n for multiples of 3).expand and simplify, then draw a clear conclusion. never use specific numbers — that is verification, not proof.
A1: 4n² + 4n = 4n(n+1); n(n+1) is even so 4n(n+1) = 8k

Watch out

g. '2 × 4 = 8'). This only shows one case, not all cases. Every step must use the general algebraic form.The conclusion must quote the original claim.

Exam-stylemulti-step

Prove that the difference of squares of two consecutive integers is always odd.

4 marks6 minsalgebraic-proof-q5

Show solution

Worked solution

1.Spot the skill: In algebraic proof: represent general cases using algebra (2n for even, 2n+1 for odd, 3n for multiples of 3).
2.Use the represent two consecutive even numbers stage first, then multiply them out.
3.Keep the final answer visible: (n+1)² − n² = 2n + 1, which is odd.

Final answer

(n+1)² − n² = 2n + 1, which is odd

Mark points

M1: use the correct in algebraic proof: represent general cases using algebra (2n for even, 2n+1 for odd, 3n for multiples of 3).expand and simplify, then draw a clear conclusion. never use specific numbers — that is verification, not proof.
A1: (n+1)² − n² = 2n + 1, which is odd

Watch out

g. '2 × 4 = 8'). This only shows one case, not all cases. Every step must use the general algebraic form.The conclusion must quote the original claim.

Grade 9 stretchproblem solving

Prove that the difference between the squares of any two consecutive odd integers is a multiple of 8.

4 marks7 minsproof-g9

Show solution

Worked solution

1.Represent consecutive odd integers as 2n + 1 and 2n + 3.
2.Subtract the smaller square from the larger and expand.
3.Factor the result to show it has a factor of 8.

Final answer

(2n + 3)² - (2n + 1)² = 8n + 8 = 8(n + 1), so the difference is always a multiple of 8

Mark points

M1: represent both consecutive odd integers generally
M1: expand and subtract correctly
A1: obtain 8(n + 1)
C1: conclude it is a multiple of 8

Watch out

Do not rush straight into arithmetic. Select the relevant method and show a complete chain of working.

Timed checkpoint

16 mins - 9 marks

Switch between skills

Set a timer and attempt all four questions before opening any answers. This is closer to the way skills appear in a real paper.

1Algebraic proof - 2 marksProve that the sum of any three consecutive integers is divisible by 3.Mark answer

Answer

n + (n+1) + (n+2) = 3n + 3 = 3(n+1), divisible by 3

2Algebraic notation and substitution - 2 marksFind t² + 4t when t = −2Mark answer

Answer

−4

3Simplifying expressions - 2 marksSimplify 2xy + 3x²y − xy + x²yMark answer

Answer

3x²y + xy

4Expanding and factorising - 3 marksFactorise fully 6x² + 9xMark answer

Answer

3x(2x + 3)

Mastery check

I can explain the method for algebraic proof.
I can show clear working without skipping key steps.
g. '2 × 4 = 8'). This only shows one case, not all cases. Every step must use the general algebraic form.The conclusion must quote the original claim.

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