Energy
- calculation of work done for constant forces, including force not along the line of motion
- calculation of exchanges between gravitational potential energy and kinetic energy
- principle of conservation of energy
The first thing to be aware of is that the recommended language for discussing energy has been changing recently. Currently the KS3 and GCSE specifications have caught up, but the students will probably not yet be familiar with it. The focus is very much on calculations, which fits very well with the quantitative approach needed at A level. The biggest change is that light, sound and current are best described as pathways or processes that explain the shifting of energy between stores. Equations can and should be used to describe the energy stored elastically, in motion and so on.
When discussing work done, it is worth reminding them that energy has been shifted to another store - usually kinetic and/or thermal (work done against friction). Some will need to be reminded that lifting an object means overcoming the weight, while others will appreciate the link between Work done = force x distance and GPE = (mg)h. You may also want to revisit their use of trigonometry when forces acting at an angle to the motion are considered.
Falling objects, or objects thrown upwards to a maximum height, offer many opportunities to link kinetic and gravitational energy store calculations. Any still relying on triangles to rearrange equations will soon struggle. Doing any classroom measurements, for example with lightgates, will show how important air resistance is with most examples. Ignoring it means that the numbers do not seem to follow the principle of conservation of energy.
This principle is one that students must be able to state clearly and explain. Challenging them to justify the common phrase of 'losing energy' will help them to appreciate that rather than energy being lost or destroyed, we are often losing track of it - an important distinction. Occasionally students will need to be reminded of the difference between energy conservation from a physics point of view, and the 'everyday' use which revolves around turning off lights.
Whilst this list provides a source of information and ideas for experimental work, it is important to note that recommendations can date very quickly. Do NOT follow suggestions which conflict with current advice from CLEAPSS or recent safety guides. eLibrary users are responsible for ensuring that any activity, including practical work, which they carry out is consistent with current regulations related to Health and Safety and that they carry an appropriate risk assessment. Further information is provided in our Health and Safety guidance.
- ALL
- Teacher guidance
- External link
Teacher guidance
Episode 214: Work Done by a Force
This introductory lesson suggests questions you might use to gauge the current understanding of your class. For many the concepts will be familiar, but the practical work allows them to extend their skills while demonstrating the principles involved. The investigation guidance - with associated prompts - uses basic equipment to show a block pulled up a slope by a hanging/falling weight. This means they will need to practise resolving forces along and into a slope, a familiar exam question.
Episode 216: Energy Changes
In this resource students consider what happens to the initial kinetic energy of a moving object. Links to braking vehicles are considered and there are practical guidelines for a useful investigation; you may see this as a chance to consolidate scientific vocabulary from your specification glossary.
As a quick reference to consider the combination of equations in specific circumstances, your students may find this list from SchoolPhysics useful.
Episode 217: Conservation of Energy
In this resource it is the sequence of practical work that is important. Students are guided in reducing causes of energy 'loss', each of which results in a closer match between the calculated values. This explicit process is one they will wish to revisit for other practicals, where they can consider ways to eliminate sources of error to improve data.
At the end of the document there are problems which could be set for homework, along with model answers and explanation.
External link
Work Done
The diagrams on this page at School Physics are particularly useful and help students to understand the effect of a force acting at an angle to the motion. They should quickly recognize the result of simple cases where the force is parallel or perpendicular to the motion, as well as the link to trigonometry for other angles.
There are not many worked examples here but they are fairly easy to generate. Alternatively you may find that challenging them to set problems for fellow students, with worked answers, helps them to gain a deeper appreciation of both the physics and the likely marking approaches taken by exam boards. Using official mark schemes and examiners' reports early on means they are more likely to show full and clear working from the beginning.
A second page at SchoolPhysics includes an explanation of the use of force-displacement graphs to calculate the work done on an object.
Calculating Work Done
A brilliant website article looking at calculating the amount of work done by forces. This resource includes the use of free body diagrams and questions to test understanding.
Energy Skate Park
This simulation from PhET allows students to change heights and slopes on a skate ramp, and then measure how the speed of a skater changes at various points on the journey. Values of both gravitational and kinetic energy are calculated from the 'measurements' taken.
It is a vivid example and the main strength lies in the small wait between making a prediction and getting an answer. Students who are familiar with the PEOE structure - Predict, Explain, Observe, Evaluate - will be able to quickly make and test hypotheses, which can be quantitative rather than simply qualitative.
The Law of Conservation of Energy
Practical Physics created by the Institute of Physics and Nuffield Foundation is a collection of experiments that demonstrate a wide range of physical concepts and ideas. Amongst the practicals are a series on energy with a set of guidance notes.
