This diagnostic question is part of a series adapted for primary aged pupils from the Best Evidence Science Teaching project for ages 11 to 14.

It helps students to understand that...

This diagnostic question is part of a series adapted for primary aged pupils from the Best Evidence Science Teaching project for ages 11 to 14.

It helps students to understand how...

This diagnostic question is part of a series adapted for primary aged pupils from the Best Evidence Science Teaching project for ages 11 to 14.

It helps students to explain what a...

This diagnostic question is part of a series adapted for primary aged pupils from the Best Evidence Science Teaching project for ages 11 to 14.

It helps students to...

This diagnostic question is part of a series adapted for primary aged pupils from the Best Evidence Science Teaching project for ages 11 to 14.

It helps students to understand how scientists classify organisms into groups based on their observable characteristics. It targets any misunderstandings pupils may...

This diagnostic question is part of a series adapted for primary aged pupils from the Best Evidence Science Teaching project for ages 11 to 14.

It helps students to understand how...

Badger Publishing has a fast-growing list of publications. These samples cover the science curriculum at Key Stages One and Two, as well as assessing students' progress at Key Stage Three.

This is a starter activity in which students describe the route of a molecule of oxygen from air in the lungs to a muscle in a leg. A simple circulation “map” is provided to enable students to trace the route from the lungs, through the heart and to the leg. The map is supplied in 2 forms
at different levels...

This resource looks at the irreversible change associated with making bread. It includes teacher guidance for activities, a recipe for chapattis, photographs and a worksheet. It also contains suggestions for teaching the topic to younger learners.
Although designed as a science resource it could also be used...

From the Centre for Science Education, and with support from Shell Education services, these materials help children to investigate forces and balance.

The materials contain a clown shape to colour in and cut out. The shape is then weighted with steel washers and balanced on a taut piece of string. Once...

From the Centre for Science Education, and with support from Shell Education services, these materials help children to investigate forces and motion.

A wide variety of buggies can be constructed and powered by a jet of air escaping from a balloon. Such a vehicle may run for a distance of 20 to 30 metres...

This resource from Wellcome Trust Sanger Institute is a practical, classroom activity that allows the students to make a balloon model of a disease-causing bacterium. This illustrates its basic shape and structure. Students can choose from three bacteria species...

This resource focusses on making a balloon powered car to learn about forces. Presenting pupils with the question, 'How do things move?' pupils explore aeroplanes and cars, learning about ‘thrust’. Through designing their own balloon-powered car, children will explore how they can increase and decrease thrust,...

A balloon provides a simple example of how a rocket engine works. The air trapped inside the balloon pushes out the open end, causing the balloon to move forward. The force of the air escaping is the “action”; the movement of the balloon forward is the “reaction” predicted by Newton’s Third Law of Motion.

This STEM activity works to develop pupils understanding of how vibrations from sounds travel through a medium to the ear. In this purposeful challenge, pupils will investigate how a balloon can be used as a simple speaker to amplify sound, by blowing up the balloon and listening to how a range of sounds travel...