A concise lesson presentation that focuses on the key details that students need to know about diodes for the GCSE examinations. The lesson begins by introducing the idea that diodes only allow current to flow in one direction. Moving forwards, time is taken to go through the potential difference vs current graph in 3 parts so that students can explain how the diode functions. Moving forwards, students will meet a LED and then in the style commonly associated with the 6 mark exam question, they are challenged to use data in a table to compare the effectiveness of a LED against other light bulbs.

This is a detailed REVISION lesson that contains an engaging powerpoint (99 slides) and is fully-resourced with associated worksheets. The lesson uses a range of activities which include exam questions (with displayed answers), differentiated tasks and quiz competitions to engage students whilst they assess their knowledge of the content that is found within topic 8 (Global challenges) of the OCR GCSE Physics A specification. The following specification points are covered in this lesson: Explain the factors which affect the distance required for road transport vehicles to come to rest in emergencies and the implications for safety Estimate how the distances required for road vehicles to stop in an emergency, varies over a range of typical speeds Estimate the forces involved in typical situations on a public road Describe the main energy sources available for use on Earth, compare the ways in which they are used and distinguish between renewable and non-renewable sources Explain patterns and trends in the use of energy resources Recall that step-up and step-down transformers are used to change the potential difference as power is transferred from power stations Link the potential differences and numbers of turns of a transformer to the power transfer involved; relate this to the advantages of power transmission at high voltages Recall that the domestic supply in the UK is a.c. at 50Hz and about 230 volts Recall the differences in function between the live, neutral and earth mains wires, and the potential differences between these wires Explain the red-shift of light as seen from galaxies which are receding (qualitative only). The change with distance of each galaxy’s speed is evidence of an expanding universe Explain how red shift and other evidence can be linked to the Big-Bang model Recall that our Sun was formed from dust and gas drawn together by gravity and explain how this caused fusion reactions, leading to equilibrium between gravitational collapse and expansion due to the energy released during fusion Recall the main features of our solar system, including the similarities and distinctions between the planets and their moons Due to the size of this revision lesson, it is likely to be used over the course of a number of lessons and can also be used throughout the duration of the GCSE course, as an end of topic revision lesson or as lessons in the lead up to mocks or the actual GCSE exams

This is a fully-resourced revision lesson which contains a wide range of activities to allow students to assess their understanding of the content in topic 2.3 (Work and energy) of the WJEC GCSE Physics specification. The engaging and detailed PowerPoint and accompanying differentiated resources use exam-style questions, tasks, discussion points and quick quiz competitions to check on the following specification points: The equation W= Fd The understanding that work is a measure of energy transfer The fact that an object can possess energy due to its motion, position and deformation Application of the equations for kinetic energy and changes in gravitational potential energy Application of the conservation of energy Understand the relationship between force and extension for a spring Application of the equation to calculate spring constant Using the force-extension graph to calculate the work done in stretching Improving the energy efficiency of vehicles

This detailed and engaging lesson has been written to challenge the students on their recall and application of the 21 equations which they have to know for the Pearson Edexcel IGCSE Physics exams. The lesson is designed to not only check that they know these equations but also on their ability to rearrange formulae when required and to convert between units. The main task of the lesson consists of 12 exam-style questions which challenge 14 of these recall equations and then an engaging quiz competition and class discussions are used to identify the other 7. Students are guided throughout the lesson in the use of the mathematical skills and are shown examples to aid their progress. This lesson has been designed to tie in with the other 8 uploaded revision lessons which cover the content of the 8 topics on the specification.

This lesson covers a large number of the key topics from the AQA GCSE Combined Physics course in the final weeks before the GCSE examinations. The extensive PowerPoint and accompanying resources use a range of activities and tasks including exam questions and quizzes to challenge the students on their knowledge of the following topics and skills: Units and converting between units Answering calculation questions (with 1 or 2 equations) Newton’s 2nd and 3rd laws of motion Resultant forces Conservation of energy Efficiency and reducing wasted energy Conservation of momentum Scalar and vector quantities Motions on a velocity-time graph The relationship between force and the extension of a spring Setting up electrical circuits Current, potential difference and resistance in series and parallel circuits The properties of ionising radiation Calculating half-lives Constructing decay equations The properties of waves Refraction This resource is likely to take 4 or more lessons to cover all of the content.

This engaging revision lesson uses a range of tasks to allow students to check their understanding of radioactive decay and nuclear radiation. The PowerPoint and accompanying resources have been designed to challenge the detail of point 4.2 of the AQA GCSE physics and combined science specifications and the following sub-topics are covered: Properties of alpha, beta and gamma Bq as the unit of radioactivity Detecting sources of radiation based on their penetrating power Half-life Decay equations Changes to the mass and charge of the nucleus after decay

A fully resourced lesson which includes an informative lesson presentation (25 slides) and an associated worksheet that show students how to give answers to a certain number of significant figures. The answers to questions in Science are often required to be given in significant figures and this lesson guides students through this process, including the rules of rounding that must be applied for success to be likely. This lesson has been designed for GCSE students but is suitable for KS3

A fully-resourced lesson that looks at the 7 electromagnetic waves, their differences, similarities and uses. The lesson includes an engaging presentation (54 slides) and associated worksheets. The lesson begins with a number of engaging activities to get the students to find out the names of the 7 waves in the spectrum. Students will be challenged to use their knowledge of the properties of waves to explain why they have been arranged in this particular order. Moving forwards, some time is taken to ensure that students recognise the similarities of the waves. The rest of the lesson focuses on the uses of the waves and a homework is also set to get students to increase the number of uses that they know for each wave. There are regular progress checks throughout the lesson so that students can assess their understanding at critical points. This lesson has primarily been designed for GCSE students (14 - 16 year olds in the UK) but could be used with students at KS3 who are doing a project

A detailed lesson presentation which guides students through calculating the current, potential difference and resistance in series and parallel circuits. The lesson begins by challenging the students to recognise whether three displayed facts relate to series or parallel circuits. Students are then given a chance to remind themselves of the differences between the circuits in terms of these three physical factors. The rest of the lesson uses a step-by-step guide format to show the students how to work through a circuit calculation by combining their knowledge of the circuit with application of the V = IR equation. Progress checks have been written throughout the lesson so that students can constantly assess their understanding. This lesson has been designed for GCSE students

A fully-resourced lesson that looks at the details of the electrical topic of resistance that students need to know for GCSE. The lesson includes a lesson presentation (21 slides) and associated worksheets. The lesson begins by looking at the meaning of resistance and focuses on the connection between resistance and current. Moving forwards, net resistance in series and parallel circuits is introduced and explained.

A resourced lesson which looks at calculating acceleration using the (v-u)/t equation. This lesson includes an engaging lesson presentation (26 slides) and a worksheet of questions that can be used for homework or during the lesson. The lesson begins by looking at the actual meaning of acceleration, ensuring that students understand it is a rate and therefore recognise the units as a result. A number of engaging activities are included in the lesson, such as the ACCELERATION OLYMPICS, to maintain motivation. Students are shown how to rearrange the equation to make velocity or time the subject and then challenged to apply these in a series of questions. Deceleration is briefly mentioned at the end of the lesson. This lesson has been primarily designed for students studying GCSE (14 - 16 year olds in the UK) but it is suitable for students at KS3 too.

A fully resourced lesson which guides students through writing decay equations to represent alpha and beta decay. This lesson includes a lesson presentation (41 slides) and differentiated worksheets. Time is taken at the beginning of the lesson to ensure that students know the sub-atomic particles that are found in an alpha particle and a beta particle so that they can understand why the atomic and mass numbers are affected during the decay. Moving forwards, a step-by-step guide is used to show students how to write both types of equations. There are regular progress checks throughout the lesson so that students can check their understanding. This lesson has been written for GCSE students (14 - 16 year olds in the UK)

An engaging, practical-based lesson presentation (22 slides), accompanied by a practical worksheet and application questions which together explore how the extension of a spring is related to force according to Hooke’s Law. The lesson begins by introducing the name of the law and looking at the equation which connects the force, extension and spring constant. As spring constant is likely to be a new term to students, time is taken to look at the definition of this key term. Students are given hints throughout the lesson about potential issues to look out for, including the unit of spring constant being N/m when the majority of springs are small enough that their extension will be measured in cm or mm. Moving forwards, students will follow the provided experimental method to carry out the investigation and produce a set of results which can be used to plot the line. The two distinct sections of the line are discussed and the actual words of Hooke’s Law are given and again discussed and considered. The final part of the lesson involves the students being challenged to apply their knowledge of the law to a range of application questions and assessing against the displayed mark scheme. This lesson has been written for GCSE students but can be used with KS3 students who are studying the extension of a spring

An engaging, practical-based lesson presentation (34 slides), accompanied by a practical worksheet and differentiated questions worksheet, which together guide students through the different calculation questions which involve the half-life. The lesson begins by introducing the students to the definition of a half-life and then showing them an example with I-131 so they can visualise how the half-life doesn’t change (and that radioactivity is measured in Bq). Moving forwards, the students will follow the given instructions to create the results to plot a decay curve and will be shown how to use this curve to determine the half-life of an isotope. The remainder of the lesson focuses on the different calculation questions that can be found on exam papers and uses a step by step guide to help them to handle the increasing difficulty. Students will be challenged to apply their new found knowledge to a set of 5 questions and this worksheet has been differentiated two ways so that those who need extra assistance, can still access the learning. Progress checks have been written into the lesson at regular intervals so that students can constantly assess their understanding. This lesson has been designed for GCSE students (14 - 16 years old in the UK)

An informative and student-led lesson presentation (32 slides), accompanied by a reaction diagram and task worksheet, which together look at the key details of nuclear fission reactions. The lesson begins by introducing the students to the name of this reaction and to that of a neutron before they are challenged to recall the properties of this sub-atomic particle as this knowledge plays an important role in their understanding. Moving forwards, students will learn that two isotopes of uranium are involved and will discover and work out how one isotope is changed into the other. Diagrams accompany the theory throughout so that students can visualise how the reaction progresses. They are shown how to work out the two daughter nuclei that are produced in the reaction and how an equation can be written to represent nuclear fission. Progress checks have been written into the lesson at regular intervals so that students can constantly assess their understanding and any misconceptions can be immediately addressed. This lesson has been designed for GCSE students (14 - 16 year olds in the UK)

A quick, concise lesson presentation (15 slides) which together with a question worksheet focuses on ensuring that students can define an isotope and pick these substances out from a selection of substances. The lesson begins by looking at the number of sub-atomic particles in an aluminium atom so that students can recall what is shown by the atomic and mass numbers. This will enable students to calculate the number of protons, neutrons and electrons in three given isotopes and as a result, complete a definition of these substances. The remainder of this short lesson involves 4 application questions where students either have to recognise isotopes from a table or from a diagram and also are asked to write out the formula of an isotope. Ideally this lesson will be taught in conjunction with a lesson on atomic structure.

This lesson has been written for GCSE students and aims to ensure that they can explain in detail why light changes direction due to refraction. The key to the explanation is the use of the correct terms in context so the start of the lesson challenges the students to come up with the key words of light, bend, normal, density and speed when given a range of clues. The next part of the lesson works with the students to bring these key terms together to form a definition of refraction. Moving forwards, the relationship between density of a medium and the speed of light through that medium is discussed so that there is a clear understanding of why light bends one way or the other. The next task uses the definition to apply to a practical situation to draw a diagram of light moving from air to glass. The final part of the lesson involves a range of practicals so this topic can be explored further.

A fast-paced lesson which includes an informative lesson presentation (20 slides) and a question worksheet. Together these resources guide GCSE students through the calculation questions that they can encounter on the topic of the conservation of momentum. The lesson begins by introducing the law of the conservation of momentum and reminding students of the equation which links momentum, mass and velocity that they are expected to recall for the GCSE exam. Time is taken to inform them of the two types of question which tend to arise on this topic - those where the masses lock together during the event and those where they remain as separate masses. Students are guided through both of these types of questions with worked examples to enable them to visualise how to begin and set out their workings. Key mathematical skills are involved such as rearranging the formula so this is also shown. Students are given the opportunity to apply these skills to a series of questions on the worksheet and the mark schemes are displayed so they can assess once completed.