Here are the six faces of a cube - in no particular order. Here are three views of the cube. Can you deduce where the faces are in relation to each other and record them on the net of this cube?
Make a cube out of straws and have a go at this practical challenge.
I've made some cubes and some cubes with holes in. This challenge invites you to explore the difference in the number of small cubes I've used. Can you see any patterns?
A game has a special dice with a colour spot on each face. These three pictures show different views of the same dice. What colour is opposite blue?
How can you paint the faces of these eight cubes so they can be put together to make a 2 x 2 cube that is green all over AND a 2 x 2 cube that is yellow all over?
Imagine a 3 by 3 by 3 cube made of 9 small cubes. Each face of the large cube is painted a different colour. How many small cubes will have two painted faces? Where are they?
Imagine a 4 by 4 by 4 cube. If you and a friend drill holes in some of the small cubes in the ways described, how many will not have holes drilled through them?
This challenge involves eight three-cube models made from interlocking cubes. Investigate different ways of putting the models together then compare your constructions.
Can you create more models that follow these rules?
The challenge for you is to make a string of six (or more!) graded cubes.
How many different cuboids can you make when you use four CDs or DVDs? How about using five, then six?
Can you make a 3x3 cube with these shapes made from small cubes?
We went to the cinema and decided to buy some bags of popcorn so we asked about the prices. Investigate how much popcorn each bag holds so find out which we might have bought.
Make a cube with three strips of paper. Colour three faces or use the numbers 1 to 6 to make a die.
Imagine you are suspending a cube from one vertex and allowing it to hang freely. What shape does the surface of the water make around the cube?
A standard die has the numbers 1, 2 and 3 are opposite 6, 5 and 4 respectively so that opposite faces add to 7? If you make standard dice by writing 1, 2, 3, 4, 5, 6 on blank cubes you will find. . . .
Let's say you can only use two different lengths - 2 units and 4 units. Using just these 2 lengths as the edges how many different cuboids can you make?
How many models can you find which obey these rules?
How can you put five cereal packets together to make different shapes if you must put them face-to-face?
When dice land edge-up, we usually roll again. But what if we didn't...?
Triangles are formed by joining the vertices of a skeletal cube. How many different types of triangle are there? How many triangles altogether?
A 3x3x3 cube may be reduced to unit cubes in six saw cuts. If after every cut you can rearrange the pieces before cutting straight through, can you do it in fewer?
A useful visualising exercise which offers opportunities for discussion and generalising, and which could be used for thinking about the formulae needed for generating the results on a spreadsheet.
In the game of Noughts and Crosses there are 8 distinct winning lines. How many distinct winning lines are there in a game played on a 3 by 3 by 3 board, with 27 cells?
What is the smallest cuboid that you can put in this box so that you cannot fit another that's the same into it?
Find all the ways to cut out a 'net' of six squares that can be folded into a cube.
This article for teachers discusses examples of problems in which there is no obvious method but in which children can be encouraged to think deeply about the context and extend their ability to. . . .
What is the greatest volume you can get for a rectangular (cuboid) parcel if the maximum combined length and girth are 2 metres?
This problem is about investigating whether it is possible to start at one vertex of a platonic solid and visit every other vertex once only returning to the vertex you started at.
Find a cuboid (with edges of integer values) that has a surface area of exactly 100 square units. Is there more than one? Can you find them all?
Is it possible to remove ten unit cubes from a 3 by 3 by 3 cube so that the surface area of the remaining solid is the same as the surface area of the original?
Imagine you have six different colours of paint. You paint a cube using a different colour for each of the six faces. How many different cubes can be painted using the same set of six colours?
Are these statements always true, sometimes true or never true?
We need to wrap up this cube-shaped present, remembering that we can have no overlaps. What shapes can you find to use?
How many faces can you see when you arrange these three cubes in different ways?
A box has faces with areas 3, 12 and 25 square centimetres. What is the volume of the box?
If you had 36 cubes, what different cuboids could you make?
Here are four cubes joined together. How many other arrangements of four cubes can you find? Can you draw them on dotty paper?
What size square should you cut out of each corner of a 10 x 10 grid to make the box that would hold the greatest number of cubes?
How can we as teachers begin to introduce 3D ideas to young children? Where do they start? How can we lay the foundations for a later enthusiasm for working in three dimensions?
Can you use small coloured cubes to make a 3 by 3 by 3 cube so that each face of the bigger cube contains one of each colour?
What is the largest cuboid you can wrap in an A3 sheet of paper?
Which faces are opposite each other when this net is folded into a cube?
How can you change the surface area of a cuboid but keep its volume the same? How can you change the volume but keep the surface area the same?
Toni Beardon has chosen this article introducing a rich area for practical exploration and discovery in 3D geometry
Which of the following cubes can be made from these nets?
How many winning lines can you make in a three-dimensional version of noughts and crosses?
A description of how to make the five Platonic solids out of paper.
This task depends on groups working collaboratively, discussing and reasoning to agree a final product.
According to Plutarch, the Greeks found all the rectangles with integer sides, whose areas are equal to their perimeters. Can you find them? What rectangular boxes, with integer sides, have. . . .