PowerPoint that covers the following learning objectives: Investigate how light travels through a lens. Describe the difference between a convex lens and a concave lens. Identify the focal point in a light ray diagram of a convex lens. This is made for a KS3 science class. Includes questions, answers, diagrams and link to a virtual simulation.

PowerPoint that covers the following learning objectives: Define the mass of an object. Measure mass of an object using a mass balance. Includes questions, pictures, instructions and a practical in which the students have to use mass balances to measure the mass of up to 20 objects. There are questions that ask students to add masses of objects together, substract masses and work out the difference. The results table, questions and space for answers are on the worksheet. This is for a primary/early secondary class. If you could spare 5 minutes, please review this resource, to help my online presence grow! :)

PowerPoint that covers the following learning objectives: Measure the temperature of a substance. Plot a graph of temperature vs. time. In this investigation, students will compare how a large beaker of hot water and a small beaker of hot water cool down differently. They will form a research question, hypothesis, fill in table of results, plot line graphs and form a conclusion. PowerPoint includes research question, hypothesis, method, graphs and conclusion. If you could spare 5 minutes, please review this resource, to help my online presence grow! :)

Appropriate for AS level physics. Print double sided (flip along long side).

This PowerPoint resource guides students through the investigation of the specific heat capacity of an object, focusing on key scientific methods and calculations. Designed to meet curriculum requirements, it includes: Starter Activity: Questions to review the definition and formulae for specific heat capacity, as well as real-life applications (e.g., why a full kettle takes longer to boil). Step-by-Step Practical Instructions: Setting up equipment, including a mass balance, immersion heater, thermometer, and electrical circuit. Recording data such as voltage, current, and temperature changes over time. Performing the experiment with and without insulation to explore energy loss. Key Equations: Includes Q=mcΔT and E=IVt for calculating energy transfer and specific heat capacity. Analysis and Interpretation: Discussion on the effect of insulation on reducing energy loss. Exploring the precision and repeatability of results. Extension ideas, such as testing different materials or types of insulation. Graphical Representation: Opportunities to plot temperature vs. time and analyze trends. Reflection and Method Writing: Students are encouraged to write a clear, repeatable method and reflect on the reliability of their results. This resource is perfect for supporting students in mastering practical skills, data analysis, and understanding energy transfer concepts in a controlled, engaging environment.

This PowerPoint presentation provides a comprehensive lesson on internal energy for science students. It begins with an engaging starter activity to review foundational concepts such as specific heat capacity, energy transfer mechanisms, and kinetic energy stores. Key learning objectives include: Defining internal energy as the sum of kinetic and potential energy of particles in a substance. Exploring how heating affects a substance’s internal energy, temperature, and state of matter. Differentiating between changes in kinetic energy and potential energy during state changes like melting, boiling, and freezing. Understanding particle arrangements and movements in solids, liquids, and gases. The presentation also includes interactive tasks like gap-fill exercises, diagrams, and detailed explanations of heating curves. Practice questions reinforce understanding and encourage critical thinking about energy transfer and particle behavior during heating and phase transitions.

This PowerPoint resource is perfect for teaching the concepts of thermal energy transfer through convection and radiation. Designed with clarity and interactivity in mind, it includes: Starter Activities: Thought-provoking questions to activate prior knowledge about heat conductors and insulators. Learning Objectives: Clearly defined goals to help students understand convection currents, describe radiation, and differentiate between heat transfer methods. Detailed Explanations: Step-by-step breakdowns of convection and radiation with real-life examples like heating in homes and energy transfer in space. Interactive Tasks: Gap-fill activities, question prompts, and diagram-drawing exercises to consolidate learning. Demonstrations: Visual examples and experiment-based questions to bring abstract concepts to life. Ideal for secondary school science lessons, this resource supports active learning and engagement.

Learning Objectives: State how energy and temperature are measured. Describe the difference between heat and temperature. Describe how energy is transferred from one object to another. Explain what is meant by thermal equilibrium.

Learning Objective: Investigate which materials are good insulators of heat. Method: Set up your boiling tubes: leave one unwrapped and wrap each of the others in a different material, using elastic bands or tape to hold the material in place. Try to make the different wrappings roughly the same thickness. Prepare lids for the containers, made out of the same material as the wrapping, if possible, otherwise made from aluminium foil or cling film. Make a hole in each lid which is just big enough for the thermometer to fit through. Use the measuring cylinder to pour 20ml of hot water into each boiling tube. Put the lids onto the containers, with a thermometer fitted through each lid so that it rests near the bottom of the water. Start the stopwatch and measure the starting temperature of the water. After 15 minutes, measure the temperature of the water in each beaker.

State what conduction is. Describe how conduction happens. Describe how solids are better conductors than liquids.

• Describe the effect of changing the mass or the force acting on an object on the acceleration of that object. • Calculate the force required to cause a specified acceleration on a given mass. • Perform calculations involving the rearrangement of the F = ma equation.

Describe the difference between mass and weight. Describe the forces acting on an object falling through a fluid. Explain what terminal velocity is and when it is reached.

Calculate the stopping distance from the thinking distance and the braking distance • Categorise factors which affect thinking distance, braking distance, and both. • Calculate the braking distance of a car.

Calculate the speed of an object, the time taken to travel a given distance and the distance travelled.

• Define what the centre of mass is and identify where it would be in a range of simple shapes. • State that a suspended object will come to rest so that the centre of mass lies below the point of suspension. • Describe an experimental technique to determine the centre of mass of an object with an irregular shape. • Compare the stability of objects to the position of their centre of mass.

Define elastic and non-elastic deformation in materials. Calculate the extension (or compression) of a material using its length and original length. State Hooke’s law and use it to calculate the force required to cause a given extension in a spring using the spring constant. Describe how elastic potential energy is stored when a material is stretched or compressed by a force. Describe force-extension graphs of elastic materials and identify the limit of proportionality. Compare the behaviour of different materials before and after the limit of proportionality.

Describe the motion of an object by interpreting distance–time graphs. Describe how the gradient of a distance–time graph represents the speed. Calculate the speed of an object by calculating the gradient from a distance–time graph.

Describe the motion of an object by interpreting velocity–time graphs. Describe how the gradient of a velocity–time graph represents the acceleration. Calculate the acceleration of an object by calculating the gradient from a velocity–time graph.