This lesson is designed for the KS3 Year 8 Science course, specifically the C2 1.3 unit on ‘Separation Techniques. More Biology, Chemistry and Physics resources can be found in my TES Shop: https://www.tes.com/teaching-resources/shop/SWiftScience The lesson begins with a ‘Think > Pair > Share’ task, students are asked to describe what happens when salt is mixed with water, using the particle model to help them with their explanation. After a short discussion, a diagram is revealed to show students what happens when more and more salt is added to water, eventually reaching a saturated solution. Students will now be provided with a definition for ‘solubility’, following this students will complete a task whereby they will match the key word to the correct definition. Students can self-assess their work once this is complete. Next, students will complete an investigation to work out how much sugar can be dissolved in 100g of water - an equipment list and method is provided for students to follow. Students will now be given some data on the solubility of two salt compounds - potassium chloride and sodium chloride - as temperature increases from 0-100 degrees celsius. They will be required to draw a graph to display this data and describe the relationship between temperature and solubility. This work can be self-assessed once it is complete, using the mark scheme provided. Lastly, students will complete a ‘copy and correct’ task where they will need to copy a paragraph into their books and make amendments so that it correctly summarises what students have learned this lesson. The plenary task is a 3-3-1 reduction, students will need to write down three facts, three key words and 1 question to test their peers knowledge of what was 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 1.3 unit on ‘Separation Techniques. More Biology, Chemistry and Physics resources can be found in my TES Shop: https://www.tes.com/teaching-resources/shop/SWiftScience The lesson begins with a recap of particle arrangements in an element, compound and a mixture. Students will be asked to ‘Think > Pair > Share’ their ideas, drawing a diagram of the particle arrangement in each as an extra challenge. After a short discussion, the answers will be revealed so students can check their work. The next task requires students to organise a set of statements into two columns - those statements describing a mixture or describing a compound. This task can then be self-assessed using the mark scheme provided once complete. Students are now asked to ‘Think > Pair > Share’ their ideas about what the term ‘pure’ means. After a short class discussion, the definitions (along with examples) for pure and impure substances are provided. Students will now complete an investigation to test three different water samples for purity. Using a pH test and an evaporation test students need to decide which of the samples are pure and which are impure. Students will have the chance to report their findings to the rest of the classroom, explaining their thoughts on which samples were pure/impure. Lastly, students will watch a video on chemical tests used to check the purity of a substance. Students will need to answer a set of questions whilst watching this video, the answers to which are included in the PowerPoint so students can self-assess their work once it is complete. The plenary task requires students to spend a minute talking to the person next to them about 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 is a homeschool pack designed for the KS3 Year 8 Science course, specifically the ‘C2.1 The Periodic Table’ unit of work. For more lessons & homeschool packs designed for KS3 and KS4, please visit my shop at: https://www.tes.com/teaching-resources/shop/SWiftScience. This comprehensive pack contains eight pages of information, to meet learning objectives within the Year 8 ‘The Periodic Table’ unit of work. This is followed by three pages of questions, differentiated to suit a range of abilities, as well as a detailed mark scheme for students/parents to mark and correct answers. The pack covers the following topics: Metals & non-metals Groups & periods The elements of Group 1 The elements of Group 7 The elements of Group 0 Thanks for looking :), if you have any questions please email me at swift.education.uk@gmail.com.

This is a homeschool pack designed for the KS3 Year 8 Science course, specifically the ‘C2.3 The Earth’ unit of work. For more lessons & homeschool packs designed for KS3 and KS4, please visit my shop at: https://www.tes.com/teaching-resources/shop/SWiftScience. This comprehensive pack contains four pages of information, to meet learning objectives within the Year 8 'The Earth unit of work. This is followed by three pages of questions, differentiated to suit a range of abilities, as well as a detailed mark scheme for students/parents to mark and correct answers. The pack covers the following topics: The Earth & its early atmosphere Sedimentary rocks Igneous & metamorphic rocks The Rock Cycle The Carbon cycle Climate change Recycling Thanks for looking :), if you have any questions please email me at swift.education.uk@gmail.com.

This is a homeschool pack designed for the KS3 Year 7 Science course, specifically the ‘C1.1 Atoms, Elements and Compounds’ unit of work. For more lessons & homeschool packs designed for KS3 and KS4, please visit my shop at: https://www.tes.com/teaching-resources/shop/SWiftScience. This comprehensive pack contains three pages of information, to meet learning objectives within the Year 7 ‘Atoms, Elements & Compounds’ unit of work. This is followed by two pages of questions, differentiated to suit a range of abilities, as well as a detailed mark scheme for students/parents to mark and correct answers. The pack covers the following topics: Atoms & Elements Compounds Chemical Formulae Thanks for looking :), if you have any questions please email me at swift.education.uk@gmail.com.

This is a homeschool pack designed for the KS3 Year 7 Science course, specifically the ‘C1.3 Chemical Reactions’ unit of work. For more lessons & homeschool packs designed for KS3 and KS4, please visit my shop at: https://www.tes.com/teaching-resources/shop/SWiftScience. This comprehensive pack contains six pages of information, to meet learning objectives within the Year 7 ‘Chemical Reactions’ unit of work. This is followed by three pages of questions, differentiated to suit a range of abilities, as well as a detailed mark scheme for students/parents to mark and correct answers. The pack covers the following topics: Chemical Reactions Word Equations Burning Fuels Thermal Decomposition Conservation of Mass Endothermic and Exothermic Reactions Thanks for looking :), if you have any questions please email me at swift.education.uk@gmail.com.

This is a homeschool pack designed for the KS3 Year 7 Science course, specifically the ‘C1.4 Acids & Akalis’ unit of work. For more lessons & homeschool packs designed for KS3 and KS4, please visit my shop at: https://www.tes.com/teaching-resources/shop/SWiftScience. This comprehensive pack contains four pages of information, to meet learning objectives within the Year 7 ‘Acids & Alkalis’ unit of work. This is followed by three pages of questions, differentiated to suit a range of abilities, as well as a detailed mark scheme for students/parents to mark and correct answers. The pack covers the following topics: Acids & Alkalis Indicators and pH Neutralisation Making Salts Thanks for looking :), if you have any questions please email me at swift.education.uk@gmail.com.

This is a homeschool pack designed for the KS3 Year 8 Science course, specifically the ‘C2.2 Separation Techniques’ unit of work. For more lessons & homeschool packs designed for KS3 and KS4, please visit my shop at: https://www.tes.com/teaching-resources/shop/SWiftScience. This comprehensive pack contains four pages of information, to meet learning objectives within the Year 8 'Separation Techniques’ unit of work. This is followed by three pages of questions, differentiated to suit a range of abilities, as well as a detailed mark scheme for students/parents to mark and correct answers. The pack covers the following topics: Mixtures Solutions Solubility Filtration, evaporation & distillation Chromatography Thanks for looking :), if you have any questions please email me at swift.education.uk@gmail.com.

This is a homeschool pack designed for the KS3 Year 7 Science course, specifically the ‘C1.2 Particles & Their Behaviour’ unit of work. For more lessons & homeschool packs designed for KS3 and KS4, please visit my shop at: https://www.tes.com/teaching-resources/shop/SWiftScience. This comprehensive pack contains six pages of information, to meet learning objectives within the Year 7 ‘Particles & Their Behaviour’ unit of work. This is followed by three pages of questions, differentiated to suit a range of abilities, as well as a detailed mark scheme for students/parents to mark and correct answers. The pack covers the following topics: The particle model & changes of state Melting & Freezing Boiling More changes of state Diffusion Gas Pressure Thanks for looking :), if you have any questions please email me at swift.education.uk@gmail.com.

This is a homeschool pack designed for the KS3 Year 8 Science course, specifically the ‘C2.3 Reactions with Metals’ unit of work. For more lessons & homeschool packs designed for KS3 and KS4, please visit my shop at: https://www.tes.com/teaching-resources/shop/SWiftScience. This comprehensive pack contains four pages of information, to meet learning objectives within the Year 8 'Reactions with Metals’ unit of work. This is followed by three pages of questions, differentiated to suit a range of abilities, as well as a detailed mark scheme for students/parents to mark and correct answers. The pack covers the following topics: Acids & Metals Metals & Oxygen Metals & Water Metal Displacement Reactions Extracting Metals Ceramics Polymers Composites Thanks for looking :), if you have any questions please email me at swift.education.uk@gmail.com.

This lesson is designed for the NEW AQA Trilogy Chemistry GCSE, particularly the ‘Organic Chemistry’ SoW. Firstly, pupils will need to complete a ‘True or False’ activity on carbohydrates, they will then be shown how polysaccharides are made from monosaccharides via a condensation reaction, as an example of a natural polymer. Pupils will also be provided with information on the structure of starch and glycogen ad how this relates to the function of these two polymers. Another example of a natural polymer are polypeptides/proteins which are made up of the monomers - amino acids. Again, pupils will be shown how a condensation reaction occurs to link together many amino acids molecules in a long polypeptide chain. Pupils will now complete a ‘Quick Check’ task to test their knowledge of what they learned so far this lesson, the answers to the questions will be provided in the PowerPoint for students to assess their own work. The next part of the lesson will focus on DNA as a natural polymer. Firstly, pupils will need to order the structures given in order of size - DNA, gene, chromosome, nucleus, cell. Next, pupils will watch a video on the structure and function of DNA and will need to answer a set of questions. This work can then be self-assessed using the answers provided in the PowerPoint. A diagram is then shown highlighting some of the key structural features of a double-helix DNA molecule, which pupils need to know and remember. The final task is a ‘Quick Check’ activity on the structure & function of DNA, students will need to answer the questions in their books and then peer or self-assess their work using the mark scheme provided. The plenary task is for pupils to write three quiz questions for pupils to test their peers knowledge of the topic learned in the lesson today. 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 Chemistry GCSE, particularly the ‘Rates of Reaction’ 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 ‘Think, Pair, Share’ task to get students thinking about what the rate of a reaction tells us about that chemical reaction. After a short partner and class discussion, the answer can be revealed to the class via the PowerPoint slide. This is followed by a task whereby students need to place a mixture of chemical reactions in order of their speed, getting students to think about which of these reactions might have the fastest rate of reaction. Students are then introduced to the two ways in which scientists can measure the rate of reaction - how much product formed/how much reactant is used up over a given time. Students will be asked to read some information about this topic and then answer questions on it, this work can be self-assessed using the answers provided in the PowerPoint. Students will then watch a video on how to calculate the rate of a reaction using a graph, students can self-assess their answers using those provided in the PowerPoint presentation. Students will then practice these skills by plotting a graph using a set of data, which they will then need to use to answer a set of questions, this can be self-assessed using the mark scheme provided. The next video outlines how students can use a graph to a work out the rate of a reaction at a fixed point, students will answer questions whilst watching the video and then self-assess their work using the answers provided. Lastly, students will again practice this skill by plotting a graph using data provided and then will need to use the graph to work out the rate of reaction at different fixed points. This work can be self-assessed using the answers provided. The plenary task is is for pupils to complete one of a choice of sentences starters, which would summarize 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 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 lessons starts with looking at the way in which we use models to represent the structure of different compounds, models include the 3D ball and stick model, 2D ball and stick model, dot and cross diagrams and displayed formula showing bonds. Pupils are reminded of the limitations of some of these models, this is something they should be able to recount. Pupils are now shown a diagram to show how intermolecular forces act between simple covalent molecules, pupils should be able to explain the difference between the strong covalent bonds between atoms but the weak intermolecular forces between molecules and how this relates to the the low melting and boiling points of simple covalent molecules. The next part of the lesson is going to focus on giant covalent structures, firstly pupils will watch a video and answer a set of questions. Their work can be self-assess using the answers provided on the PowerPoint presentation. Students are then introduced to the three main covalent structures - diamond, graphite and silicon dioxide. Students will be given a set of information on these structures which they will need to use to complete their worksheet on giant covalent structures. To assess their knowledge of this topic there is a set of ‘quick check’ questions, pupils of a higher ability may want to complete these questions in the back of their books without discussing with others. The work can be assessed using the mark scheme provided. The last part of the lesson focuses on fullerenes and graphene - two other giant covalent structures with unique properties. Students are firstly introduced to the structure and uses of these compounds before watching a video and answering questions about them. The work from this task can be self or peer assessed using the answers provided. The plenary task is for pupils to pretend they are a scientist researching the use of nanotubes, fullerenes and grapehene, they need to come up two ideas of how these materials can be used in future technologies. 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 Chemistry GCSE, particularly the 'Atomic Structure & Periodic Table' 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 an introduction into the sub-atomic particles that make up an atom, pupils will need to fill in a diagram and statements to describe the position of each of these particles. Pupils will then be shown the charges and relative mass of each of these particles for a couple of minutes during a 'memory test' activity, they will then try and copy the information down into their books from memory. Next is a mid-lesson progress check where pupils will need to answer questions off the board in pairs. In the next half of the lesson pupils are introduced to the idea of atomic and mass numbers, they are firstly asked to use their periodic table to identify the atomic and mass numbers of certain elements. This work is self-assessed and then pupils are asked to think about how the number of neutrons could be calculated, once revealed pupils are then given a large table to complete to identify the atomic number mass number, plus the number of protons, neutrons & electrons for the first 20 elements. The plenary task is an exit card where pupils can identify the areas in which they feel confident with this topic and those areas they feel they need more practise with. 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 ‘Chemical calculations’ 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 relative atomic mass, including an explanation of how we can use the periodic table to find the atomic masses of different elements. In order to assess their understanding of this topic pupils will then complete a table identifying the atomic number, mass number and the number of electrons/protons/neutrons found within atoms of specific elements. This task can then be assessed using the answers provided in the PowerPoint presentation. Pupils will now think about what the formula of a chemical compound tells us about the elements found in that compound. Using examples pupils will be taught about formulae, they will then be given a list of formulae for various different chemical compounds and will need to list the different elements found in that compound as well as the number of atoms of each of the elements. This task can then be assessed using the answers provided. The next part of the lesson will focus on relative formula mass, pupils will be taught, using a worked example, how to calculate the relative formula mass for a chemical compound. They will then need to complete tasks involving the calculations of relative formula mass, once complete pupils can self-assess their work using the answers provided. The last part of the lesson focuses on moles, the definition is first introduced to pupils which can be explained further using the link the video included in the PowerPoint. Pupils are then shown how to calculate the number of moles of a substance using the relative formula mass and actual mass of a substance. Pupils will be then need to complete a set of calculations to work out the moles of different substances, this task can be assessed using the answers provided. Pupils are lastly shown how to rearrange this calculation where needed, they can then apply this skill to a new set of problems. The answers to which are included in the PowerPoint presentation, pupils can use this to assess their work. 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 begins with a recap on the differences between elements, compound and mixture, pupils complete a task and self-assess their work. Pupils are then introduced to the idea of covalent bonding and ionic bonding as two forms of bonding and are reminded how to draw the electronic configuration of an atom, including a reminder of the rules around filling energy shells. Pupils will now watch a video on the formation of ions, whilst watching the video pupils will answer a set of questions and when finished pupils can assess their work using the answers provided in the PowerPoint. Next, pupils will be shown how to draw diagrams to demonstrate the formation of positive and negative ions, they can draw examples in their books for future reference. To assess their knowledge of this topic pupils will complete a set of questions including drawing a diagram to demonstrate the formation of an ionic bond between lithium and fluorine, this can then be self or peer assessed using the answers provided. The last task is for pupils to use their periodic table to draw the electronic structure of the ions formed from a potassium, oxygen, magnesium and calcium atom. This work will then be assessed using the answers provided. The plenary involves pupils picking a task, wither write a twitter message about what they have learnt or write a set of quiz questions to test peers on what they have learnt in the 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 Chemistry GCSE, particularly the ‘Chemical changes and electrolysis’ 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 Students are firstly introduced to the idea of a displacement reaction using an example of aluminium and iron oxide, pupils will then be given a list of chemical reactions and for each one students will need to decide whether a displacement reaction will occur. Students will now conduct an investigation whereby they will place a metal - copper, magnesium, iron and zinc - into copper sulphate solution and observe what happens. Using the results from this investigation, students should decide on the order of reactivity of these metals. Students are now given another list of reactions, for each one students need to now decide if a displacement reaction will take place and if so write out the word equation for each. Students can mark their work using the answers provided. The next part of the lesson focuses on oxidation and reduction, firstly students are provided with a definition of these two processes. They are then shown how to write an ionic half equation to demonstrate what is happening what is happening during a displacement reaction, which metal has been oxidised and which has been reduced. Pupils need to complete the ionic half equations for a list of reactions, pupils can assess their work against the answers provided on the PowerPoint presentation. The last task is a progress check, students need to work their way through a set of questions to assess what they have learnt this lesson. The answers to which are included on the PowerPoint slides forstudents to self-assess or peer-assess their work. The plenary task is for pupils to write a twitter message about what they learnt this lesson, no more than 140 characters and #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 'Earth’s Resources’ 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 task whereby pupils need to use their phones/laptops to research the dates in which different metals were discovered. They should complete the table in their books and then write a sentence to summarise the relationship between the date in which the metal was discovered and it’s reactivity. The first part of the lesson now focuses on extraction of copper from copper-rich ores, two methods are firstly introduced - smelting and extraction using sulfuric acid. Pupils will then be given a set of information on these processes and will need to answer a set of questions, once complete pupils can self-assess their work using the answers provided. The next part of the lesson will require pupils to undertake a practical investigation whereby they will extract copper from an ore called malachite, an ore which contains copper carbonate. Students will need to follow the instructions provided and will then need to note down their observations of the electrode at which the copper will collect. A summary and explanation of the results will then be provided via the PowerPoint presentation for pupils to check their work. Lastly, pupils will watch a video about low-grade copper ores and the processes of phytomining and bioleaching for the extraction of copper from such ores. Pupils will need to answer a set of questions whilst watching this video, this work can be self-assessed using the mark scheme provided. The plenary task is for pupils to write a list of key words from what they have learned in the lesson today. All resources are included at the end of the presentation. Thanks for looking, if you have any questions please email me at swift.education.uk 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 Students are firstly introduced to collision theory, outlining the conditions which need to be in place in order for a chemical reaction to occur. Next students are asked to ‘Think, Pair, Share’ factors which they think may affect the rate of a reaction, once students have had chance to discuss this they are introduced to the four main factors which they study within this topic. Firstly, the lesson will focus on surface area, this factor is explained using apple slices turning brown as an example, students are then introduced to the relationship between surface area to volume ratio and the rate of reaction. Students will then need to complete a worksheet of surface area to volume ration calculations, this can then be self-assessed using the mark scheme available. Students will now work through a set of levelled questions looking at data on the effect of surface area on the rate of reaction, this work can be self-assessed using the mark scheme provided in the PowerPoint presentation. The next part of the lesson will focus on the effect of temperature on the rate of reaction, students will firstly need to answer questions whilst watching a video, this work can then be self-assessed using the mark scheme. Next, students will carry out an investigation into the effect of temperature on the rate of reaction between sodium thisulphate and hydrochloric acid. Students will need to collect data and use this to work out the rate of reaction at different temperatures, a worksheet is provided for this task. The last task is for pupils to complete a ‘Quick Check’ set of questions in order to assess what they have learned this lesson, students can then either peer-assess or self-assess their work using the mark scheme provided. The plenary task is for pupils to write a twitter message about what they have learned this lesson, included a hashtag 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 :)