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 the Carnot cycle. Describe how an internal combustion engine works. Explain why latent heat is needed in a steam turbine. 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.

Resource was intended for BTEC Applied Science Unit 1 Physics. The resource was designed on google slides and should work fine on powerpoint, it might just need some rearranging. Past paper questions are included with answers from the mark scheme. By the end of the lesson learners will be able to: Identify waves of the EM spectrum. Describe the uses of EM waves. Compare the use of microwaves and radio waves in communication.

Resource was intended for BTEC Applied Science Unit 1 Physics. The resource was designed on google slides and should work fine on powerpoint, it might just need some rearranging. Past paper questions are included with answers from the mark scheme. By the end of the lesson learners will be able to: 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.

By the end of the lesson learners will be able to: Identify standing and progressive waves. Describe how to produce a standing wave. Explain why resonance can be dangerous.

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 a system in which work and heat is used. Describe the first law of thermodynamics Calculate specific heat and specific latent heat 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.

Resource was intended for BTEC Applied Science Unit 1 Physics. The resource was designed on google slides and should work fine on powerpoint, it might just need some rearranging. Past paper questions are included with answers from the mark scheme. By the end of the lesson learners will be able to: Identify digital and analogue signals. Describe how digital signals store information. Compare single mode and multimode fibre.

Resource was intended for BTEC Applied Science Unit 1 Physics. The resource was designed on google slides and should work fine on powerpoint, it might just need some rearranging. Answer keys are included for all questions asked. By the end of the lesson learners will be able to: Identify what is meant by refraction. Describe the following during refraction: incident ray, refracted ray, normal, angle of incidence and angle of refraction. Using Snell’s equation calculate the angle of refraction.

By the end of the lesson learners should be able to: State what is meant by standard deviation. Describe how to calculate standard deviation. Create error bars from data and place correctly on a graph.

By the end of the lesson learners will be able to: Identify waves from a top view. Describe what occurs during diffraction. Explain why a diffraction grating produces light and dark zones.

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 equations for efficiency. Describe how to calculate efficiency by using heat in and heat out. Explain how the Carnot Revolution equation is derived. 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 equations involving work done by movement and work done by pressure expansion. Describe how the area of cylinder heads affect the movement of fluids in hydraulics. Use multiple equations to calculate the work, force and distance moved by hydraulic cylinders. 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 second law of thermodynamics. Describe what is meant by natural processes and entropy. Compare adiabatic and isothermal processes. 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 ideal gas equation. Describe how scientists calculated absolute zero. Evaluate different thermometers. 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.

A comprehensive lesson which teaches students about Hooke’s law, the spring constant equation, Stress strain graphs and how to calculate Young’s modulus based on this. Lesson is tailored towards the AQA A-level physics specification - Mechanics and Applied Science level 3 Edexcel Unit 5 Physics. LO: To evaluate stress/strain graphs to determine Young’s modulus and apply this to situations. By the end of the lesson learners should be able to: Success criteria: SC1: Recall Hooke’s law and identify limits of proportionality and plastic deformation on a graph. SC2: Describe how to calculate Young’s Modulus from a tensile stress-strain curve. SC3: Explain why rubber is effective at cushioning shocks. For the a-level content: as a separate document included as pdf. 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. For btec unit 5 applied science: questions are on the slides following the lesson. Powerpoint contains 27 slides and 12 past paper questions.

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.

A comprehensive lesson which teaches students about Hooke’s law, the spring constant equation, Stress strain graphs and how to calculate Young’s modulus based on this. Lesson is tailored towards the AQA A-level physics specification - Mechanics and Applied Science level 3 Edexcel Unit 5 Physics. By the end of the lesson learners should be able to: LO: Evaluate stress/strain graphs to discern brittle, ductile and malleable objects. Success criteria: SC1: Recall the trends shown during a strain/stress curve. SC2: Compare malleability and ductility. SC3: Explain why malleability and ductility are important in producing, tubes, screw caps and lead sheets. For the a-level content: as a separate document included as pdf. 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. For the BTEC applied science level 3: The resource contains past paper questions and mark scheme answers attached to the slides. Powerpoint contains 27 slides and 9 past paper questions. Slides were originally created using google slides, opening in microsoft powerpoint might cause slight misalignment - open in google slides to avoid this.

By the end of the lesson learners will be able to: Identify the 3 transfers of heat. Describe each process of heat transfer. Explain why double glazed windows reduce the amount of heat loss in a home.

Lessons created to match the activate 3 scheme of work. All features work when used with google slides. All features should all work with powerpoint but might need some rearranging. By the end of the lesson learners will be able to: State what is meant by reaction time. Describe how technology is used in sport. Explain why technology saves lives during crashes.