This lesson is designed for the NEW AQA Trilogy Chemistry GCSE, particularly the ‘Structure & Bonding’ SoW. For more lessons designed to meet specification points for the NEW AQA Trilogy specifications for Biology, Chemistry and Physics please see my shop: https://www.tes.com/teaching-resources/shop/SWiftScience The lesson starts with students being introduced to the regular, crystal structure of a metal. To demonstrate the formation of metal crystals pupils can complete a simple practical activity whereby they place a piece of copper wire in silver nitrate solution, a displacement reaction occurs and silver metal crystals begin to form on the surface of the copper. Pupils can complete this task using the set of instructions included on the PowerPoint slide and write down their observations in their books. The next part of the lesson focuses on linking the structure of a metal to it’s properties, once this has been demonstrated to students using the information and diagrams included in the PowerPoint presentation they can copy and complete a worksheet to assess what they have learned. Once this task is complete students can assess their work using the mark scheme provided. Now pupils will look at metal alloys, firstly pupils will watch a video and answer a set of questions. Pupils can then self-assess their work using the answers provided. The last part of the lesson is on the properties of metals and how their properties relates to their uses, each student will be given a card of information describing a property of a metal. Pupils will walk around the room discussing the information they have on their card with others and using each other they should be able to complete a table of properties in their books. The plenary task requires pupils to come up with three facts, two key words and a question to test their peers on the topic of metallic bonding. All resources are included at the end of the presentation. Thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This lesson is designed for the NEW OCR GCSE (Gateway) Biology ‘Cell-level systems’ SoW. For more lessons designed to meet specification points for the NEW GCSE specifications for Biology, Chemistry and Physics please see my shop: https://www.tes.com/teaching-resources/shop/SWiftScience This lesson begins with an introduction of the process of aerobic respiration including the word equations that pupils will need to learn. Next is a video, pupils will need to answer questions whilst watching the video, once it is finished they can self-assess their work using the mark scheme provided. Pupils are then introduced to the idea that aerobic respiration is exothermic and look specifically at the ultra-structure of the cell and which parts are important for respiration, this activity is a match up activity that pupils can complete and then mark. A mid-plenary is a true or false task and the final activity is a levelled worksheet pupils will complete using information cards on how animal and plant organisms use the energy released by respiration. Once finished they can self-assess using the mark scheme on the PowerPoint slides. Pupils have a choice of two activities to complete for their plenary - either an anagram challenge or a summary sentence using a list of key words. All resources are included at the end of the presentation. Thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This is a lesson which meets specification points in the NEW AQA GCSE (2016) 'Cells' SoW. Other lessons from this SoW and other AQA GCSE Trilogy Sow for the new specification can be found in my TES shop. This lesson begins by watching a video about the structure of cells and where to find the genetic information, pupils will watch the video and answer questions (provided in the PowerPoint presentation.) Pupils will then be presented with a labelled diagram of a cell, nucleus, chromosome and gene. Pupils will be required to analyse the diagram for a few minutes (you can include a stop clock on the board). The screen will then be changed and pupils will be given a blank copy of the diagram which they will need to complete from memory - pupils can then peer-assess their work. In the next activity, pupils are shown diagrams of a cell with a nucleus visible, DNA, a gene and a chromosome. Pupils can either create a flow chart by cutting and sticking the diagrams in order from largest to smallest and then labelling them. Alternatively, they could draw their own diagrams and label them. Pupils can then self-assess their work using red pens. The next activity, pupils are given a series of words and definitions, they will need to match the key words up to the correct definition. Pupils then self-assess their work. Their are two option for the plenary activity, for lower ability classes pupils will be required to fill in the blanks in a paragraph describing the structure and function of genetic information and where it is found within the cell. The second plenary is a past-paper question, pupils can answer this in their books and then peer-assess using red pens. All resources are included, please leave a review with feedback :). Thanks!

This lesson is designed for the KS3 Year 8 Science course, specifically the C2 1.2 unit on ‘Metals & Other Materials’. For more lessons designed for KS3 and KS4 please visit my shop at: https://www.tes.com/teaching-resources/shop/SWiftScience. The lesson begins with a demonstration of magnesium being burned in air. Students should write down their observations and try to write the complete word equation for magnesium + oxygen, the answer can then be revealed to the class using the PowerPoint. Students will now complete an investigation into how different metals react when burned with oxygen in air. Students should follow the practical worksheet, filling in the table provided with their observations, using their observations they will be asked to place the metals in order of reactivity. This task can be checked against the answers provided on the PowerPoint presentation when completed. Students will now compete a task whereby they will write a set of word equations into their books, making sure they fill in the blanks as they go. The mark scheme for this task is included in the PowerPoint so students can assess their work once it is complete. Students will then be shown how to include state symbols for balanced chemical equations, using this knowledge students will now need to write out the balanced symbol equations (including state symbols) for a set of metal + oxygen reactions. Students can self-assess their work once this is complete. The last task is a role-play, students will each be given either an element or a compound card. Music will be played and students can move/dance around the room, when the music stops they need to get together and line up to form a ‘metal + oxygen -> metal oxide’ word equation. The teacher can check that students have got together and lined up in the correct order! The plenary task requires students to write a twitter message about what they have learned this lesson, they should include #keywords. All resources are included at the end of the presentation. Thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This lesson is designed for the KS3 Year 8 Science course, specifically the C2 1.2 unit on ‘Metals & Other Materials’. For more lessons designed for KS3 and KS4 please visit my shop at: https://www.tes.com/teaching-resources/shop/SWiftScience. The lesson begins with a recap on the reactivity series, students will be asked a seris a questions about certain metals found within the series. Students should be able to identify the metals based upon knowledge learned in previous lessons, once complete this task can be self-assessed using the mark scheme provided. Students will now be introduced to the idea of a ‘displacement reaction’ as a reaction where a more reactive metal found in the reactivity series will displace a less reactive metal. An example is shown - aluminium oxide + iron -> aluminium oxide + iron. Students will then be give a set of reactions, without the products written in, they will need to decide whether a displacement reaction will take place or not. This work can then be marked and corrected using the mark scheme provided. Students will now complete an investigation ‘Competition in Metals’. Students will follow the steps provided on the investigation worksheet to identify whether a displacement reaction has occurred between a number of metals + metal solutions. Students will fill in a results table as they go, noting down any observations as well as identifying if a reaction took place or not. Students can check their answers against the example results table found in the PowerPoint presentation. Lastly, students will complete a ‘True or False’ task, they will be given a set of statements and will need to identify whether they are true or false. This work can be peer or self assessed using the mark scheme provided. The plenary task requires students to complete a sentence starter, from the choice provided, in order to summarise what they have learned this lesson. All resources are included at the end of the presentation. Thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This lesson is designed for the KS3 Year 8 Science course, specifically the C2 1.2 unit on ‘Metals & Other Materials’. For more lessons designed for KS3 and KS4 please visit my shop at: https://www.tes.com/teaching-resources/shop/SWiftScience. The first task is for pupils to research, either using their phones or using laptops, the dates at which different metals were discovered. Once they have found the dates and filled in their table, they should consider the link between the reactivity of the metal and when it was discovered. After a class discussion of their ideas, students are introduced the idea of a metal ore. The next task is for pupils to watch a video and answer questions on metal extraction, the answers to which are included in the PowerPoint presentation so students are able to self-assess their work. The next part of the lesson focuses on how metals can be extracted from their ores, firstly students will be shown the position of carbon within the reactivity series. They will then be told that any metal below carbon in the reactivity series is able to be extracted from its oxide by a reaction with carbon. The general word equation for this reaction is shown to students, they can make a note of this in their books. They will then be asked to write down the complete word equations for the reactions of copper, iron and zinc with carbon. The mark scheme for this is provided on the PowerPoint presentation for students to mark and correct their work once complete. Lastly, students need to be able to work out the amount of metal present in an ore. A worked example of this calculation is shown to students, they can make a note of the steps when approaching a question of this sort in their books. They will be then given a worksheet of questions to answer which requires students to calculate the masses of useful metal found in metal ores, as well as the waste. The mark scheme for this task is included in the PowerPoint so students can self or peer assess their work once it is complete. The plenary requires students to write a Whatsapp message to friends, explaining what they have learned this lesson. All resources are included at the end of the presentation. Thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This lesson is designed for the NEW AQA Trilogy Biology GCSE, particularly the ‘Bioenergetics’ SoW. For more lessons designed to meet specification points for the NEW AQA Trilogy specifications for Biology, Chemistry and Physics please see my shop: https://www.tes.com/teaching-resources/shop/SWiftScience Pupils will learn about the products made during photosynthesis and how these are used plants. In particular the uses of protein, cellulose, starch and fats & oils. At a higher level pupils will consider the advantages and disadvantages of energy storage molecules such as fats, oils & starch. Pupils will have an opportunity to use information points around the room to complete a levelled worksheet on this topic which will be peer assessed at the end of the lesson. Extension opportunities are available if finished. Once this first activity has been self or peer assessed pupils will then have the opportunity to conduct an experiment to investigate the presence of starch in normal and variegated leaves. The last activity pupils will complete are two exam-style questions on the topic of the lesson, this can then be self-assessed. All resources are included at the end of the presentation. Thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This lesson is designed for the NEW AQA Physics GCSE, particularly the ‘Forces in Action’ SoW. For more lessons designed to meet specification points for the NEW AQA Trilogy specifications for Biology, Chemistry and Physics please see my shop: https://www.tes.com/teaching-resources/shop/SWiftScience The lesson begins with an introduction to moments, using a spanner. Students are then introduced to the calculation - moment = force x distance from the pivot. Students are then shown a worked example using the calculation, before being presented with a problem to solve themselves. Next, students are shown a diagram of a man pushing down on one side of a see saw, at the other side is a bag of money. This diagram is labeled to show the effort force, pivot and load. Students are then given a worksheet on levers, students will need to identify the effort force, pivot and load in each of the diagrams and also match the key words to the correct definition. This work can be self-assessed using the mark scheme provided once it is complete. The last two tasks are assessment tasks, firstly students will copy and complete the paragraph, using the key words provided, to summarise what they have learned this lesson. This can then be self-assessed using the mark scheme provided. Lastly, students are presented with a set of moment problems, using the calculation they learned at the beginning of the lesson students will need to work through these calculations. The mark scheme for this task is also included so students can self-assess or peer-assess their work. Lastly, students will be shown a diagram of apparatus which can be used to investigate the turning effect of a force. Students are asked some questions about this investigation, they will then need to complete a ‘Quick Check’ task which will assess students knowledge of what they have learned this lesson. This task can then be self-assessed using the mark scheme provided. The plenary task requires students to copy and complete a sentence starter to summarise what they have learned this lesson. All resources are included at the end of the presentation, thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated The plenary task requires students to write a Whatsapp message to summarise what they have learned this lesson. All resources are included at the end of the presentation. Thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This lesson is designed for the NEW AQA Physics GCSE, particularly the ‘Radioactivity’ SoW. For more lessons designed to meet specification points for the NEW AQA Trilogy specifications for Biology, Chemistry and Physics please see my shop: https://www.tes.com/teaching-resources/shop/SWiftScience This lesson begins with a recap on background radiation, students need to create a mind map in their books of the different source of background radiation. Once this task is complete students can mark their work against the answers provided. This is followed by a task whereby students will complete a worksheet about background radiation, the mark scheme for this task is included so students can self-assess their own work. Next, pupils will need to recap their knowledge of the dangers of alpha, beta and gamma radiation. Students will need to copy and complete a table which summarises the dangers of these three types of radiation, inside and outside the body. Students can self-assess this task once it has been completed, using the mark scheme provided. The next part of the lesson focuses on radioactive waste, firstly students are given some information about the type of waste that is produced by a nuclear power plant. Students will then watch a video on the topic, during which they will need to answer a set of questions. This work can be marked and corrected using the answers provided. Students are now shown information about Chernobyl and Fukishima, two videos on the topics help to demonstrate the ideas written on the PowerPoint presentation. This is followed by some details of designs for new nuclear reactors which will be built in the next 20 years, students need to understand the advances made in safety and design for third-generation nuclear reactors. Lastly, pupils will complete a set of exam-style questions on radioactivity. This work can be self-assessed using the mark scheme provided. The plenary requires pupils to come up with questions for a set of answers that are provided on the PowerPoint. All resources are included at the end of the presentation. Thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This lesson is designed for the KS3 Year 8 Science course, specifically the P2 1.2 unit on ‘Energy’. More Biology, Chemistry and Physics resources can be found in my TES Shop: https://www.tes.com/teaching-resources/shop/SWiftScience This lesson starts with a task whereby students will watch a video on infrared radiation, they will need to try to come up with a definition for infrared radiation whilst watching. The answers that students come up with can then be marked and corrected using the answer provided. Students will then be shown a diagram of a Leslie’s cube, and are told that different surfaces emit different amounts of infrared radiation. Students will then be asked to make a prediction about the surface they think (out of a choice of surfaces) will emit the most radiation. Students will then complete an investigation into the amount of infrared radiation given off by different coloured tins - black or silver. Once complete, students can use the data they have collected to draw a graph of their results and complete the analysis questions. Students will then be given examples of how infrared radiation can be absorbed and reflected and why these two processes are useful. Following on from this, students will complete a ‘fill-in-the-blank’ task to summarise what they have learned this lesson, this task can be self-assessed using the mark scheme provided. The plenary task is a ‘pick a plenary’ task, students are asked to either summarise what they have learned in three sentences or write a definition for a list of key words provided. All resources are included at the end of the presentation, thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This lesson is designed for the NEW AQA Trilogy Physics GCSE, particularly the 'Electricity’ SoW. For more lessons designed to meet specification points for the NEW AQA Trilogy specifications for Biology, Chemistry and Physics please see my shop: https://www.tes.com/teaching-resources/shop/SWiftScience The lesson starts with an introduction into the differences between series and parallel circuits, students can take notes and draw a diagram of each type of circuit in their books. Students will then watch a video on series and parallel circuits, they will need to answer a set of questions in their books which focuses on how current and potential difference across components changes in a series vs. parallel circuit. Once this task is complete, students can then self-assess their work using the mark scheme provided. Next, pupils have to identify whether a circuit is a series circuit or a parallel circuit from a set of diagrams. Then, students are given a worksheet of parallel and series circuits, given the current of the ammeter shown in the diagram they will need to work out the current of the ammeters placed elsewhere in the circuit. Students can then self or peer assess their work using the mark scheme provided. The next part of the lesson focuses on the resistance of components found in series and parallel circuits. Firstly, students will be given the ‘Resistance Rule’ for components in a series circuit, as well as the calculation to work out total resistance in a series circuit. Using this, students can then answer some questions which can be self-assessed using the mark scheme provided. Next, pupils are introduced to the ‘Resistance Rule’ for components placed in a parallel circuit. Once they have learned the rules, pupils can answer a set of questions which can then be either peer-assessed or self-assessed using the mark scheme provided. The plenary task is a ‘Pick a plenary’ task - students can either summarise what they have learned this lesson in three sentences or they can write a definition for a set of key words from the ‘Electricity’ topic. All resources are included at the end of the presentation. Thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This lesson is designed for the NEW AQA Trilogy Physics GCSE, particularly the 'Electricity’ SoW. For more lessons designed to meet specification points for the NEW AQA Trilogy specifications for Biology, Chemistry and Physics please see my shop: https://www.tes.com/teaching-resources/shop/SWiftScience The lesson begins with a video on electrical current and charge flow, students will need to answer a set of questions whilst they are watching the video. This work can then be self-assessed using the mark scheme provided. Next, is a ‘Quick Check’ task where students will need to answer a set of questions using the calculation for rate of charge flow. Students will need to show their working for each of these questions, the answers are provided on the PowerPoint presentation so students can check their work against the mark scheme, making corrections where needed. Next, the lesson introduces the formula for calculating the energy transferred to components within a circuit. Students can take notes using the PowerPoint presentation and then using the formula they should work their way through another ‘Quick Check’ task. The mark scheme for this task is also included in the PowerPoint presentation for pupils to self or peer assess their work. The final part of the lesson focuses on energy transfers within a circuit. Firstly, a worked problem is shown to students before they have a go at working their way through another ‘progress check’, using knowledge of what they have learned so far this lesson. The plenary task requires pupils to write a twitter message about what they have learned in the lesson, this must include #keywords! All resources are included at the end of the presentation. Thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This lesson is designed for the NEW AQA Trilogy Chemistry GCSE, particularly the ‘Structure & Bonding’ SoW. For more lessons designed to meet specification points for the NEW AQA Trilogy specifications for Biology, Chemistry and Physics please see my shop: https://www.tes.com/teaching-resources/shop/SWiftScience The lesson starts with a set of questions on ionic compounds, pupils will watch a video and answer these questions. Then pupils will be shown a diagram to demonstrate the structure of a giant ionic compound and will be given a set of melting points for a range of ionic compounds, pupils will need to think > pair > share why they think the melting points of ionic compounds are so high. Once students have considered this, a class discussion can reveal some of the students ideas before the presentation moves on and explains why ionic compounds have high melting and boiling points. Students are now given a place-mat of questions, using information from the lesson so far they will need to complete part of it, for lower-ability students they may need extra support such as a text book to help them answer the questions. Once complete pupils can assess their work using the answers provided. The next part of the lesson focuses on electrolysis using ionic compounds, students are shown that only ionic compounds that are molten or dissolved in water are able to conduct electricity. The process of electrolysis is demonstrated to students using an animation . Pupils are then asked to thin > pair > share their ideas on why ionic compounds that are solid cannot conduct electricity. Once some ideas have been discuss as a class, the answer can be revealed on the PowerPoint presentation. Pupils will now complete the remainder of their questions on their place-mat and mark them using the answers provided. Pupils will now be given a set of ions and will need to decide whether they will be found at the positive or negative electrode, this activity can be done as a whole class by pupils holding up answers using whiteboards or in their books. Once completed students can assess their work using the answers provided. The last activity is for pupils to complete a cartoon strip to demonstrate what happens to molten potassium fluoride when it is used to conduct electricity. Part of the cartoon strip is filled in already, pupils just need to add in either diagrams or descriptions, this can also be assessed once complete. The plenary task is a set of answers, pupils need to come up with a set of questions for these answers. All resources are included at the end of the presentation. Thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This lesson is designed for the NEW AQA Trilogy Biology GCSE, particularly the ‘Ecology’ SoW. For more lessons designed to meet specification points for the NEW AQA Trilogy specifications for Biology, Chemistry and Physics please see my shop: https://www.tes.com/teaching-resources/shop/SWiftScience The first task is for pupils to consider the ways in which scientists can measure water pollution. Pupils will need to match the piece of equipment to the description of how it is used. Pupils can then assess their work using the answers provided. The next task is for pupils to think about living indicators of pollution, they can think > pair > share their ideas about what living organisms might give us an idea of the pollution levels in the local environment. After a class discussion the information on the PowerPoint slide will outline some of these examples of bio-indicators. The next task focuses on water bio-indicators, pupils will be in groups and one at a time get a chance to look at a poster of organisms which live in polluted to unpolluted water. Pupils will view the poster and then have to go back to their desks to try and recreate as much of it as they can. After a set period of time (as it could go on forever!) pupils can then assess their work against the poster and see how well they did. The next part of the lesson focuses on bioaccumulation of chemicals in marine organisms, pupils will have the chance to read through an article and will need to use the information in the article to come up with their own definition of ‘bioaccumulation’. Once pupils have completed this task you can reveal the definition for bioaccumulation and a diagram to simply depict how this process occurs in marine environments. The last part of the lesson looks at eutrophication, pupils will firstly watch a video about this process and will need to answer questions whilst watching. Once this is complete they can mark their work using the answers provided. Finally pupils will be given a blank cartoon strip, for which they will need to select the correct captions to go with the correct stage in the process of eutrophication as well as draw a diagram to depict this stage. The plenary task for pupils is for them to pretend they work for an environmental charity, they need to tweet a message to raise awareness abut the effect water pollutants can have on local biodiversity. All resources are included at the end of the presentation. Thanks for looking, if you have any questions please let me know in the comments section and any feedback would be appreciated :)

This is a lesson aimed at the new AQA Physics GCSE module on 'Energy'. For more lessons within this series please visit my shop: https://www.tes.com/teaching-resources/shop/SWiftScience The lesson begins by introducing the concept of 'work done', by using the example of a person pedalling a bike. The first task the pupils will need to complete is to produce a mind map on activities which require work to be done in order something to happen. Pupils are then shown the equation to calculate work done and they can work through a model question. You can work through this question with pupils on the board or ask them to try and complete it in their books, then self-assess the work. The main activity for this lesson is a practical activity, the method for this practical is included in the PowerPoint presentation. Pupils will drag a wooden block across the desk a measured distance, the wooden block will be dragged initially with no elastic bands around it and then with one elastic band and finally with two elastic bands. Pupils will measure the force applied to drag the block using a Newton meter and record their results in a table (table included at the end of the PowerPoint). Using the measured distance and the force applied pupils can then work out the work done to drag each type of wooden block. The plenary activity is for pupils to complete a couple more work done calculations. All resources are included in the PowerPoint presentation.