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Sieve of Eratosthenes — Hunt Prime Numbers on a Grid
Mark

Created by

Mark

2. July 2026FI
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Sieve of Eratosthenes — Hunt Prime Numbers on a Grid

A hands-on maths project for the classroom: make a hundred-square, then cross out the multiples of each number with counters until only the prime numbers are left. A Python cell checks the 25 primes you find, and a compendium explains why primes are the building blocks of every number.
Beginner
30 minutes

Instructions

1

What is a prime?

A prime number can only be split into equal groups as one big group or as single ones -- 5, 7 and 11 are primes. Every other number can be built by multiplying smaller ones. Around 240 BC Eratosthenes found a simple way to sift the primes out, and you will do it by hand.
2

Make a hundred-square

On a sheet of card rule a 10 by 10 grid and write the numbers 1 to 100 in it, ten to a row. This is your sieve.

Materials for this step:

Cardstock Assorted Pack (50 sheets)Cardstock Assorted Pack (50 sheets)1 piece

Tools needed:

Graphite Pencil SetGraphite Pencil Set
Steel Ruler (30cm)Steel Ruler (30cm)
3

Cross out the multiples

Cross off 1 (not prime). Circle 2, then place a counter on -- or cross out -- every other multiple of 2: 4, 6, 8, and so on. Move to the next uncrossed number, 3, circle it, and cross out every third number. Do the same for 5 and 7. Once you pass 10 you can stop. Every number still uncrossed is prime -- count them: there should be 25.

Materials for this step:

Glass BeadsGlass Beads1 piece
4

Check the primes you found

Loading Jupyter Notebook...

Tools needed:

Desktop ComputerDesktop Computer
5

Compendium: the atoms of arithmetic

What your grid shows. (1) Every whole number above 1 is either prime or breaks down into primes in exactly one way -- the Fundamental Theorem of Arithmetic -- so primes are the 'atoms' that build all the other numbers. (2) You only had to cross out multiples up to the square root of 100 (that is, 10), because any larger composite already got crossed by a smaller factor -- a neat shortcut worth thinking about. (3) Primes get rarer as numbers grow, but never run out (Euclid proved there are infinitely many). (4) The hunt for large primes and the difficulty of un-multiplying big numbers is exactly what keeps online banking and messaging secure today.

Materials

2

Tools Required

3

You can swap these in

Can't get one of the materials? Swap it for an equivalent — these work just as well.

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