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A comprehension lesson that teaches students about how the eye and the camera treat light. Students will have the opportunity to create a simple pinhole camera. Progress checks are available following each success criteria Tasks are differentiated to suit the needs of each learner. Learning objective: Compare how the eye and the camera interpret light differently. By the end of the lesson learners should be able to: Success criteria: Identify parts of the camera and the eye. Describe how light is processed by the camera and the eye. Compare the eye and the camera. Powerpoint contains 15 slides.

A comprehensive lesson which teaches students about errors, uncertainties and how these can be represented as error bars. This lesson was designed to fit needs of the AQA a-level physics course Tasks are differentiated to suit the needs of each learner. Learning objective: Understand and apply the concepts of measurement uncertainties. By the end of the lesson learners should be able to: Success criteria: 1: Identify random and systematic errors. 2: Calculate different types of uncertainties. 3: Represent uncertainties on graphs. Powerpoint contains 29 slides. Contains past paper questions that target this topic, some questions require knowledge from prior lessons.

A revision poster that includes material needed for section 8 of the edexcel iGCSE combined science double award physics. Section 8 - Astrophysics A blank copy for students to fill in is also included for students to test their knowledge. I would recommend to print these in A3 and guide the students through the answers using the completed revision poster attached. Due to the amount of detail needed to squeeze into one poster, the font is small in some sections which might need some further zooming in on presenting devices.

This is a lesson I used myself to teach the Reflection, Fibre optics and endoscopes concept of the waves Unit - A level Physics, AQA specification. I’ve also used this lesson to teach BTEC applied science unit 1 physics (Level 3) Learning objective: Describe how total internal reflection is utilised in optics. Explain why cladding improves this. By the end of the lesson learners should be able to: Success criteria: Identify the critical angle. Describe the uses of optical fibres. Explain why endoscopes are able to obtain an image of an object even if the optical fibre inside is curved. Identify the critical angle. Describe the uses of optical fibres. Explain why endoscopes are able to obtain an image of an object even if the optical fibre inside is curved. Contains past paper questions that target this topic, some questions require knowledge from prior lessons. Powerpoint contains 52 slides and 6 past paper questions.

A collection of 4 revision mats for students to fill (answer sheets are included) - I found it has been useful to zoom in on selected parts on the projector as students check their notes on the sheet. Notes are condensed for the following topics: Electricity, Magnetism, Matter, Forces and Energy. Slides were originally produced on google slides, please open them as google slides to avoid formatting issues.

By the end of the lesson learners will be able to: Identify low, mid and high energy waves. Describe how to protect yourself from exposure to energy waves. Explain why there is strict government guidelines for the use of gamma and X-rays

By the end of the lesson learners should be able to: Identify the waves of the EM spectrum. Describe how frequency and wavelength change throughout the EM spectrum. Explain why radio waves can be used safely.

By the end of the lesson learners should be able to: Identify permanent and induced magnets. Describe what’s meant by a permanent and induced magnet. Explain why magnets are used in industry.

A comprehensive lesson that teaches students about electromagnets and how how magnetic fields are produced in a current carrying conductor. Solenoids as coils of wire that are able to behave as a bar magnets when a current is present in them. Progress checks are available following each success criteria Tasks are differentiated to suit the needs of each learner. By the end of the lesson learners should be able to: Learning objective: Explain why current can generate electromagnets and how to change their properties. Success criteria: State what is created when current flows through a wire. Describe how to increase the magnetic field strength. Explain why solenoids are used in industry. Powerpoint contains 18 slides. Contains past paper questions and mark scheme answers to use as a plenary.

A comprehensive lesson which teaches students Newton’s laws of motion from simple separate scenarios. Lesson is tailored towards the AQA A-level physics specification - Mechanics Learning objective: I can apply Newton’s laws to scenarios. By the end of the lesson learners should be able to: Success criteria: SC1: Describe how Newton’s first law applies to objects in motion. SC2: Explain why mass affects an object’s acceleration. SC3: Evaluate why a reaction force is present. Contains past paper questions that target this topic, some questions require knowledge from prior lessons. There is also a guide attached with written walkthroughs of how to reach the final answer, even for those tricky 1 mark questions. Powerpoint contains 27 slides and 7 past paper questions.

A comprehensive lesson which teaches students how to read motion graphs, calculate horizontal and vertical motion in projectiles using SUVAT equations and explain the effect of drag on projectiles leading to terminal velocity. Lesson is tailored towards the AQA A-level physics specification - Mechanics Tasks are differentiated to suit the needs of each learner. Learning objective: Use SUVAT equations to calculate projectile motion. By the end of the lesson learners should be able to: Success criteria: SC1: I describe components of displacement-time and velocity-time graphs. SC2: I can use and manipulate SUVAT equations. SC3: I can calculate components of projectile motion. Contains past paper questions that target this topic, some questions require knowledge from prior lessons. There is also a guide attached with written walkthroughs of how to reach the final answer, even for those tricky 1 mark questions. Powerpoint contains 17 slides and 13 past paper questions.

A comprehensive lesson which teaches students conservation of momentum, elastic and inelastic collisions, impulse graphs and how these link to change in momentum. Lesson is tailored towards the AQA A-level physics specification - Mechanics Learning objective: Calculate momentum and apply this to justify force changes during collisions. By the end of the lesson learners should be able to: Success criteria: SC1: Calculate momentum. SC2: Compare elastic and inelastic collisions. SC3: Explain why impulse graphs show force outputs. Contains past paper questions that target this topic, some questions require knowledge from prior lessons. There is also a guide attached with written walkthroughs of how to reach the final answer, even for those tricky 1 mark questions. Powerpoint contains 18 slides and 13 past paper questions.

A comprehensive lesson which teaches students about resistance and how this impacts voltage distribution in a potential divider circuit. This lesson was designed to fit needs of the AQA a-level physics course - unit 5 electricity. Tasks are differentiated to suit the needs of each learner. Learning objective: Explain why a potential divider is used in appliances. By the end of the lesson learners should be able to: Success criteria: I describe how to calculate the total resistance in a variety of circuits. I can explain why a potential divider is used. I can calculate the voltage output using the potential divider equation. Powerpoint contains 24 slides. Contains past paper questions that target this topic, some questions require knowledge from prior lessons.

A comprehensive lesson which teaches students about factors that influence electrical current. This lesson was designed to fit needs of the AQA a-level physics course - unit 5 electricity. Tasks are differentiated to suit the needs of each learner. Learning objective: To explain the fundamental concepts of electrical current, potential difference, electromotive force, including their definitions, units of measurement, and relationships to each other. By the end of the lesson learners should be able to: Success criteria: SC1: Define and distinguish between current, potential difference electromotive force SC2: Explain the relationships between current, potential difference and emf. SC3: Derive the P = IV equation from two different equations. Powerpoint contains 44 slides. Contains past paper questions that target this topic, some questions require knowledge from prior lessons.

A comprehensive lesson which teaches students about Fleming’s Left Hand Rule, the motor effect and applying this to a simple motor. Students will also be able to use the F = BIL equation quantify the amount of force experienced by a wire. Progress checks are available following each success criteria Tasks are differentiated to suit the needs of each learner. Learning objective: Use and apply the left hand rule in order to justify the movement of a wire within a magnetic field. By the end of the lesson learners should be able to: Success criteria: I can identify the components of the left hand rule. I can justify the motion of the wire based on the rule. I can explain why motors are able to spin. Powerpoint contains 22 slides and a collection of past paper questions including the marking scheme.

Originally created for the BTEC Applied Science level 3 qualification Unit 5 - Physics. By the end of the lesson learners should be able to: Recall the difference between Newtonian and Non-Newtonian fluids Describe pseudoplastic, dilatant, thixotropic, and rheopectic fluids. Justify the uses of these different fluids. The resource contains past paper questions and mark scheme answers. Slides were originally created using google slides, opening in microsoft powerpoint might cause slight misalignment - open in google slides to avoid this.

Originally created for the BTEC Applied Science level 3 qualification Unit 5 - Physics. By the end of the lesson learners should be able to: Recall that imperfections can lead to cracks forming in a material. Describe how tension is expressed in a material and how cracks can lead to a concentration of stress which eventually leads to brittle fractures. Justify why creep and fatigue are factors that must be accounted for by engineers. The resource contains past paper questions and mark scheme answers. Slides were originally created using google slides, opening in microsoft powerpoint might cause slight misalignment - open in google slides to avoid this.

Originally created for the BTEC Applied Science level 3 qualification Unit 5 - Physics. By the end of the lesson learners should be able to: Recall the equipment needed for moving heat. Describe how altering the set-up of the system can lead to refrigeration or a heat pump being created. Use the coefficient of performance calculations for a heating system. The resource contains past paper questions and mark scheme answers. Slides were originally created using google slides, opening in microsoft powerpoint might cause slight misalignment - open in google slides to avoid this.

Defnyddais google slides are gyfer addysgu’r wers hon. Ddylai bod o’n gweithio yn yr un modd drwy Microsoft PowerPoint ond efallai fydd angen ailosod rhai agweddau. Erbyn diwedd y wers ddylech fod yn gallu: Adnabod beth sydd yn achosi’r Haf a’r Gaeaf Disgrifio sut mae’r Haul yn ymbelydru golau. Egluro’r cysylltiad rhwng gogwyddo’r Ddaear â’r Tymhorau.

A comprehension lesson that teaches students how to measure force using practical equipment as well as calculate resultant forces. Progress checks are available following each success criteria Tasks are differentiated to suit the needs of each learner. Learning objective: Develop an understanding of how forces interact within a pair or multiples in perpendicular directions. By the end of the lesson learners should be able to: Success criteria: State how forces are represented. Describe how to calculate the resultant force. Calculate forces in horizontal and vertical directions. Powerpoint contains 30 slides.