Work with numbers big and small to estimate and calculate various quantities in physical contexts.

An introduction to a useful tool to check the validity of an equation.

Get some practice using big and small numbers in chemistry.

Work with numbers big and small to estimate and calculate various quantities in biological contexts.

Formulate and investigate a simple mathematical model for the design of a table mat.

Could nanotechnology be used to see if an artery is blocked? Or is this just science fiction?

What's the chance of a pair of lists of numbers having sample correlation exactly equal to zero?

Can you find some Pythagorean Triples where the two smaller numbers differ by 1?

We think this 3x3 version of the game is often harder than the 5x5 version. Do you agree? If so, why do you think that might be?

Work out the numerical values for these physical quantities.

In which Olympic event does a human travel fastest? Decide which events to include in your Alternative Record Book.

Investigate constructible images which contain rational areas.

All types of mathematical problems serve a useful purpose in mathematics teaching, but different types of problem will achieve different learning objectives. In generalmore open-ended problems have. . . .

What shapes should Elly cut out to make a witch's hat? How can she make a taller hat?

Explore the properties of combinations of trig functions in this open investigation.

Two polygons fit together so that the exterior angle at each end of their shared side is 81 degrees. If both shapes now have to be regular could the angle still be 81 degrees?

This article (the first of two) contains ideas for investigations. Space-time, the curvature of space and topology are introduced with some fascinating problems to explore.

Two perpendicular lines lie across each other and the end points are joined to form a quadrilateral. Eight ratios are defined, three are given but five need to be found.

How much peel does an apple have?

Many natural systems appear to be in equilibrium until suddenly a critical point is reached, setting up a mudslide or an avalanche or an earthquake. In this project, students will use a simple. . . .

Where should runners start the 200m race so that they have all run the same distance by the finish?

A description of some experiments in which you can make discoveries about triangles.

It starts quite simple but great opportunities for number discoveries and patterns!

In a snooker game the brown ball was on the lip of the pocket but it could not be hit directly as the black ball was in the way. How could it be potted by playing the white ball off a cushion?

This tricky challenge asks you to find ways of going across rectangles, going through exactly ten squares.

The letters of the word ABACUS have been arranged in the shape of a triangle. How many different ways can you find to read the word ABACUS from this triangular pattern?

How will you decide which way of flipping over and/or turning the grid will give you the highest total?

A follow-up activity to Tiles in the Garden.

Use trigonometry to determine whether solar eclipses on earth can be perfect.

Take any pair of numbers, say 9 and 14. Take the larger number, fourteen, and count up in 14s. Then divide each of those values by the 9, and look at the remainders.

In this investigation, we look at Pascal's Triangle in a slightly different way - rotated and with the top line of ones taken off.

Where we follow twizzles to places that no number has been before.

There are three tables in a room with blocks of chocolate on each. Where would be the best place for each child in the class to sit if they came in one at a time?

How many different sets of numbers with at least four members can you find in the numbers in this box?

Numbers arranged in a square but some exceptional spatial awareness probably needed.

In this article for teachers, Bernard gives an example of taking an initial activity and getting questions going that lead to other explorations.

Take ten sticks in heaps any way you like. Make a new heap using one from each of the heaps. By repeating that process could the arrangement 7 - 1 - 1 - 1 ever turn up, except by starting with it?

On a "move" a stone is removed from two of the circles and placed in the third circle. Here are five of the ways that 27 stones could be distributed.

A challenging activity focusing on finding all possible ways of stacking rods.

Investigate how this pattern of squares continues. You could measure lengths, areas and angles.

Place the 16 different combinations of cup/saucer in this 4 by 4 arrangement so that no row or column contains more than one cup or saucer of the same colour.

An investigation involving adding and subtracting sets of consecutive numbers. Lots to find out, lots to explore.

Place four pebbles on the sand in the form of a square. Keep adding as few pebbles as necessary to double the area. How many extra pebbles are added each time?

This article for teachers suggests ideas for activities built around 10 and 2010.