How fast would you have to throw a ball upwards so that it would never land?

Get some practice using big and small numbers in chemistry.

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

Work out the numerical values for these physical quantities.

Have you got the Mach knack? Discover the mathematics behind exceeding the sound barrier.

An article demonstrating mathematically how various physical modelling assumptions affect the solution to the seemingly simple problem of the projectile.

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

Ever wondered what it would be like to vaporise a diamond? Find out inside...

Get further into power series using the fascinating Bessel's equation.

Build up the concept of the Taylor series

We all know that smoking poses a long term health risk and has the potential to cause cancer. But what actually happens when you light up a cigarette, place it to your mouth, take a tidal breath. . . .

See how enormously large quantities can cancel out to give a good approximation to the factorial function.

Given the equation for the path followed by the back wheel of a bike, can you solve to find the equation followed by the front wheel?

Look at the advanced way of viewing sin and cos through their power series.

By exploring the concept of scale invariance, find the probability that a random piece of real data begins with a 1.

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?

Explore the properties of this different sort of differential equation.

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

Dip your toe into the fascinating topic of genetics. From Mendel's theories to some cutting edge experimental techniques, this article gives an insight into some of the processes underlying. . . .

Read about the mathematics behind the measuring devices used in quantitative chemistry

Unearth the beautiful mathematics of symmetry whilst investigating the properties of crystal lattices

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.

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.

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

How much peel does an apple have?

Investigate constructible images which contain rational areas.

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

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

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. . . .

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?

Investigate x to the power n plus 1 over x to the power n when x plus 1 over x equals 1.

Which parts of these framework bridges are in tension and which parts are in compression?

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

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

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

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

There has been a murder on the Stevenson estate. Use your analytical chemistry skills to assess the crime scene and identify the cause of death...

Fancy learning a bit more about rates of reaction, but don't know where to look? Come inside and find out more...

Looking at small values of functions. Motivating the existence of the Taylor expansion.

Draw three equal line segments in a unit circle to divide the circle into four parts of equal area.

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?

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?