A google slides resource that is ready to be used out of the box. Slides might need some alterations when opened with powerpoint. By the end of the lesson learners will be able to: State the units for energy Compare the energy values of foods and fuels Compare the energy in foods and fuels with energy needed for different activities A practical lesson is also included for calorimetry. Risk assessment, hypothesis, results tables (+ class results) and evaluations are included.

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 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 that teaches students about magnetic poles, magnetic filed lines and how these field lines impact attraction and repulsion. Progress checks are available following each success criteria Tasks are differentiated to suit the needs of each learner. Learning objective: To justify the effects of magnetic field lines in repulsion and attraction. By the end of the lesson learners should be able to: Success criteria: -Identify the poles on a magnet. -Describe the direction of magnetic field lines. -Explain the effect of combining magnetic field lines. Powerpoint contains 27 slides.

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.

Resource prepared for BTEC Applied science Level 3 - Unit 3. By the end of the lesson learners should be able to: Identify circuit symbols. Describe how energy usage can be calculated. Explain why fuses are used.

By the end of the lesson learners will be able to: Identify the uses of alpha, beta and gamma radiation. Describe how they are used in real world applications. Explain why the type of radiation is suited for the role it carries out.

By the end of the lesson learners should be able to: State what is meant by the habitable zone. Describe how we can communicate with aliens on other planets. Explain why the light we receive on Earth from a star / exoplanet can tell us about its elemental makeup.

By the end of the lesson learners will be able to: Identify the forces working during a crash. Describe how the reduce the crashing force. Explain why crumple zones and slower driving cause less damage during a crash.

A revision poster that includes material needed for section 1 of the edexcel iGCSE combined science double award physics. Section 1 - Forces and Motion 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.

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.

A collection of revision resources for Pearsons combined science 9-1 edexcel specification: Physics paper 3. Sometimes referred to as Physics paper 1. The resources were originally produced on google slides, therefore, please open them using google slides in order to avoid alignment issues on powerpoint. Included in this collection are: Blank revision posters for the students to fill and consolidate their knowledge. Answer keys for the revision posters OR revision slides to complement the blank revision posters. Topics covered are: Section 17 Key concepts of Physics - Motion, Forces and Energy, Section 18 EM spectrum Section 19 Radiation The entire resource contains 69 slides.

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.

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.

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.

A comprehension lesson that teaches students how to create and analyse Sankey Diagrams. The concept is introduced in the context of money to firstly engage the students (dirham currency is used as the students I taught were in the UAE, however, this should be fairly simple to understand as it is labelled below). Support sheets are also included to guide students should it be needed. Tasks are differentiated to suit the needs of each learner. Progress checks are placed after each success criteria checkpoint to assess understanding. By the end of the lesson students should be able to: Success criteria: I can critically analyse a Sankey diagram to identify quantifiable components. I can construct and adapt Sankey diagrams I can calculate efficiency of a system from its Sankey diagram. Learning objective: Develop and interpret Sankey diagrams to visualize and analyze complex data flows. Powerpoint contains 33 slides and a lesson plan is also attached.

A comprehensive lesson which teaches students about orbits, how their instantaneous velocity impacts their orbital radius and stability and how to calculate orbital speeds. Learning objective: Explain why orbital speeds change during elliptical orbits. By the end of the lesson learners should be able to: Success criteria: I can describe how orbital speeds change with the size of the orbit. I can compare the different types of orbits. I can calculate orbital speeds. Powerpoint contains 28 slides. Contains past paper questions that target this topic, some questions require knowledge from prior lessons.

By the end of the lesson learners should be able to: Identify carrier waves. Describe how waves can be modulated by amplitude or frequency. Explain why radio receivers are often able to detect a signal over a large area.

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.