How high will a ball taking a million seconds to fall travel?
Explore the energy of this incredibly energetic particle which struck Earth on October 15th 1991
Read all about electromagnetism in our interactive article.
Show that even a very powerful spaceship would eventually run out of overtaking power
Gravity on the Moon is about 1/6th that on the Earth. A pole-vaulter 2 metres tall can clear a 5 metres pole on the Earth. How high a pole could he clear on the Moon?
An article demonstrating mathematically how various physical modelling assumptions affect the solution to the seemingly simple problem of the projectile.
A look at different crystal lattice structures, and how they relate to structural properties
Derive an equation which describes satellite dynamics.
Some explanations of basic terms and some phenomena discovered by ancient astronomers
Find out how to model a battery mathematically
Problems which make you think about the kinetic ideas underlying the ideal gas laws.
How fast would you have to throw a ball upwards so that it would never land?
Where will the spaceman go when he falls through these strange planetary systems?
Explore the Lorentz force law for charges moving in different ways.
A think about the physics of a motorbike riding upside down
Look at the units in the expression for the energy levels of the electrons in a hydrogen atom according to the Bohr model.
Explore the power of aeroplanes, spaceships and horses.
A look at a fluid mechanics technique called the Steady Flow Momentum Equation.
A ball whooshes down a slide and hits another ball which flies off the slide horizontally as a projectile. How far does it go?
A look at the fluid mechanics questions that are raised by the Stonehenge 'bluestones'.
Can you match up the entries from this table of units?
This is the technology section of stemNRICH - Core.
Can you work out the natural time scale for the universe?
Follow in the steps of Newton and find the path that the earth follows around the sun.
Find out some of the mathematics behind neural networks.
See how the motion of the simple pendulum is not-so-simple after all.
Find out why water is one of the most amazing compounds in the universe and why it is essential for life. - UNDER DEVELOPMENT
Investigate some of the issues raised by Geiger and Marsden's famous scattering experiment in which they fired alpha particles at a sheet of gold.
What is an AC voltage? How much power does an AC power source supply?
An introduction to a useful tool to check the validity of an equation.
Many physical constants are only known to a certain accuracy. Explore the numerical error bounds in the mass of water and its constituents.
Get some practice using big and small numbers in chemistry.
Dip your toe into the world of quantum mechanics by looking at the Schrodinger equation for hydrogen atoms
Things are roughened up and friction is now added to the approximate simple pendulum
When a mixture of gases burn, will the volume change?
An article about the kind of maths a first year undergraduate in physics, engineering and other physical sciences courses might encounter. The aim is to highlight the link between particular maths. . . .
Look at the calculus behind the simple act of a car going over a step.
This is the area of the advanced stemNRICH site devoted to the core applied mathematics underlying the sciences.
Ever wondered what it would be like to vaporise a diamond? Find out inside...
Investigate why the Lennard-Jones potential gives a good approximate explanation for the behaviour of atoms at close ranges
Which units would you choose best to fit these situations?
Estimate these curious quantities sufficiently accurately that you can rank them in order of size
Which line graph, equations and physical processes go together?
Have you got the Mach knack? Discover the mathematics behind exceeding the sound barrier.
How does the half-life of a drug affect the build up of medication in the body over time?
Explore the rates of growth of the sorts of simple polynomials often used in mathematical modelling.
Can you arrange a set of charged particles so that none of them start to move when released from rest?
Work out the numerical values for these physical quantities.
Work in groups to try to create the best approximations to these physical quantities.
Explore how can changing the axes for a plot of an equation can lead to different shaped graphs emerging