A full KS3 scheme of work that contains six fully resourced lessons to allow your department to complete a Science Fair project. As a school we conducted this period for a two week cycle after half term to allow students to; produce an idea, write a hypothesis, plan a method, conduct an experiment of their choice and make their project. Class winners were chosen and then allowed to present their work in the hall for the rest of the school to see. This is the third year we have completed our science fair at my school. This year we had four entries that won prizes at the big bang fair regional competition. One of which was chosen as the Young scientist of the year regional winner and will be presenting their project nationally later next year. This pack contains: Assembly PowerPoint: To present to the whole school introducing the fair. Lesson 1: Producing an idea Lesson 2: Forming a Method Lesson 3: Pilot experiment Lesson 4: Experimental time Lesson 5: Conclusion and evaluation (making project) Lesson 6: Choosing a winner Lesson plans, resources and example project winners also included. I hope, if you are willing for a bit of chaos, that you see the same enthusiasm and creativity in your students as I have. good luck!

Students are introduced to Alexander Litvenenko and his "alleged" murder. Students are introduced to the idea of a half-life and how that rate can be used to calculate how long material has been decaying and analyzing material composition. Practical experiment: students use M&M sweets to draw a half life curve. by dropping M&M's and eating the sweets that land 'M' up (following lab safety of course) and plotting their findings. Repeating until they have none left. Students complete a worksheet to workout which material killed Alexander Litvenenko.

Students use their understanding of mass and weight to test how high they can jump on different planets. Using metre rulers, calculators and some enthusiasm students can multiply their average jump by the relative mass of each of the planets in the solar system. This lesson was pitched to a low ability class that needed an active way to practice their mathematics skills.

Lesson 1 Students are introduced to Seismic activity and watch a short bang goes the theory clip. Students design a simple experiment in which they drop a tray of water a time how long it takes to travel. Students consider: -a hypothesis -Controls -Method and diagram Students have adequate time to complete the experiment to get an average and summarise briefly. Lesson 2 Students process their data on a simple graph and evaluate their work. Students use the knowledge from the last two lesson to write an extended piece of writing.

Students recap the GPE and KE calculations with a ball rolling down a hill. Students are introduced to the idea of energy transference in a pendulum and the conservation of energy. (if Your feeling brave) you can attach a 1kg weight to the projector and swing it away from your chin to demonstrate that energy cannot be created. Alternatively play the video... Students then write a six mark question and are given feedback to improve (with green pen if you wish).

-Students discuss particular issues Santa may have on his Christmas eve journey (E.g. Military airspace...) -Teacher runs through a range of slides that considers, mass, air resistance, calories consumed, alcohol limits, speed, and amount of time needed. -Students are introduced to the question "How many carrots are needed to feed the reindeer during the journey" -Students complete a simple burning food experiment to test dried carrots (available at most good retailers) and other foods such as crisps, and bread to test which produce the most energy. -Higher students can try extrapolating up to find out how many carrots are needed. HINT it is over 900,000.... but remember they are magical. insert carrotometer joke where appropriate.

The slides contain a series of thought processes and frameworks so teachers can model out load their approach for students to use during comprehension and reading of scientific ideas. The lesson could be adapted for other topics. This lesson focuses on an end of Year test including: Acids and alkalis, homeostasis, energy stores and transfers, the particle model and reflection/refraction. Lesson content -Students complete a recap quiz. -Students complete a reading task in which they synthesis the data to title paragraphs and write one question. -Students get into groups and circulate around the room reading an exam question, completing an answer, and folding it over so the next group cannot see their answer. Once back at their stations they draft a final answer to share to the class based on the class responses. -Meta cognition slides and exam style practice.

Student's use simple pieces of equipment to choose a suitable material to pad the inside of Iron man&'s armor. Students then evaluate their choice. This can be completed over two lessons to allow adequate planning time.

Using a classic conduction experiment to investigate which material will prevent Gordon Ramsey burning himself in the future. Students produce a conclusion and an evaluation of their findings.

Students rearrange the common equations into formula triangles and learn how to rearrange more complex formulae such as the kinetic energy calculation. Students use their sheet to find a range of treasure (questions...) around the room.

KS3 problem solving lesson to discover what caused a train to crash. Students develop an understanding of whether or not solids, liquids and gases can be compressed using a simple experiment. Students use the results from their experiment to explain whether air leaking into the brakes may have caused the crash.

Students challenge preconceptions by investigating the unusual question. Students develop a definition of an echo and use this knowledge to test how fast sound travels outside in the courtyard. Along with a series of sound clips, students use the evidence they have gathered to write a levelled question.

Students are introduced to Democritus and his ideas of divisibility. Building on KS2 knowledge, students use plasticine to build models of solids, liquids and gases in groups. Using the idea that syringes of water and sand cannot be compressed, students rework their models to demonstrate the density of liquids. Teacher uses a simple demonstration of: floating and sinking, compression and shape to reinforce the idea of the "particle model". Students complete their findings independently.

-Students watch a clip from the Big bang Theory where Sheldon dresses as the "Doppler effect". -Students are introduced to the concept through the PowerPoint and demonstrate the effect outside through a "controlled scream drive-by". -Students complete a series of questions related to the concept to demonstrate understanding. The lesson finishes through applying their new knowledge to Sonic-booms.

Students recap their understanding of momentum using an example of a baseball player, and a person firing a gun. Students are introduced to the idea of increase the time taken to stop can decrease the amount of force. Students use this idea to discuss bicycle helmets and air bags. Students use their new understanding to complete a summary poster.

Students identify the adaptations of a magical reindeer and remind themselves of the GPE and Power equations to calculate how many calories each reindeer would need to fuel their journey on christmas eve. Students burn a range of food (including dried carrots) to see how much energy is stored in each and to extrapolate up how many carrots (in grams) would the reindeers need to eat. Ho Ho Ho.

Students design an experiment to test the strength of a rope bridge to see if Indianna Jones could safely cross it while carrying the Ark...

Using a range of simple equipment to plan a simple but precise thermometer based on Galileo's ideas. The final pieces of equipment can then be used in a competition to find a mystery temperature and then evaluated.

Student's plan a simple experiment to see what colour iron man suit emits the least amount of heat energy.