This is a concise revision resource which has been designed to cover the crucial details of topic C5 (Electricity and chemistry) of the CIE IGCSE Combined Science specification, for examination in June and November 2020 and 2021. The topic of electrolysis is commonly assessed in the examinations so time was taken during the design to ensure that understanding is constantly checked so that any misconceptions are addressed. The following content receives particular attention in this revision lesson: The use of the terms electrolyte, electrode, cathode and anode Understanding that solid ionic compounds cannot be used in electrolysis, but only electrolytes when molten or in aqueous solution The attraction of positive ions to the cathode and the gain of electrons The attraction of negative ions to the anode and the loss of electrons Predicting the products at the electrodes The lesson finishes with a summary task about the electrolysis of aluminium oxide where students have to apply their knowledge. This sheet has been differentiated two ways so that students of different abilities are able to complete the task

This revision resource has been designed to include a range of activities that will engage the students whilst they assess their understanding of the content of topic C2 (Experimental techniques) of the CIE IGCSE Combined Science specification for examination in June and November 2020 and 2021. Exam questions, quick tasks and quiz competitions such as “SEPARATE the FACT from the FICTION” will challenge the students on their recall of the content as well as their ability to apply this knowledge. The lesson was written to cover as much of the content as possible, but the following topics have received particular attention: • Simple distillation and fractional distillation Choosing appropriate apparatus Experimental and investigational skills Crystallisation and filtration Paper chromatography Calculating the retention factor This resource contains an engaging PowerPoint (45 slides) and associated worksheets and is ideal for use at the end of this topic or in the lead up to mocks or the actual terminal exams

This revision lesson has been designed to challenge the students on their use of a range of mathematical skills that could be assessed on the AQA GCSE Combined Science papers. The mathematical element of the AQA GCSE Combined Science course has increased significantly since the specification change and therefore success in those questions which involve the use of maths can prove to be the difference between one grade and another or possibly even more. The engaging PowerPoint and accompanying resources contain a wide range of activities that include exam-style questions with displayed mark schemes and explanations so that students can assess their progress. Other activities include differentiated tasks, class discussion points and quick quiz competitions such as “YOU DO THE MATH” and “FILL THE VOID”. The following mathematical skills (in a scientific context) are covered in this lesson: The use of Avogadro’s constant Rearranging the formula of an equation Calculating the amount in moles using mass and relative formula mass Calculating the relative formula mass for formulae with brackets Using the Periodic Table to calculate the number of sub-atomic particles in atoms Changes to electrons in ions Balancing chemical symbol equations Converting between units Calculating concentration in grams per dm cubed and volumes of solutions Calculating size using the magnification equation Using the mean to estimate the population of a sessile species Calculating percentages to prove the importance of biodiversity Calculating percentage change Calculating the acceleration from a velocity-time graph Recalling and applying the Physics equations Understanding prefixes that determine size Leaving answers to significant figures and using standard form Helpful hints and step-by-step guides are used throughout the lesson to support the students and some of the worksheets are differentiated two ways to provide extra assistance. Due to the detail of this lesson, it is estimated that it will take in excess of 3 hours of GCSE teaching time to cover the tasks and for this reason it can be used over a number of lessons as well as during different times of the year for revision.

This fully-resourced lesson has been written to prepare students for the range of mathematical-based questions that they may face on the two OCR GCSE Chemistry papers. The lesson has been designed to contain a wide range of activities which includes 8 quiz competition rounds spread across the duration of the lesson to maintain engagement whilst the students assess their understanding. The mathematical skills covered in this lesson include: Calculating the number of sub-atomic particles in atoms and ions Writing chemical formulae for ionic compounds Identifying isotopes Using Avogadro’s constant to calculate the number of particles Calculating the relative formula mass Calculating amount in moles using the mass and the relative formula mass Balancing chemical symbol equations Calculating reacting masses Gas calculations using molar volume Calculating concentration of solutions Titration calculations Deducing the empirical formula Calculating energy changes in reactions Most of the resources have been differentiated two ways to allow students of differing abilities to access the work whilst still being challenged. In addition, step by step guides are used to demonstrate how to carry out some of the more difficult calculations such as the harder mole calculations and calculating masses in reactions This lesson could be used with higher ability students on the OCR GCSE Combined Science course by taking out the sections which are not applicable.

This lesson explains how to use the endings -ide and -ate when naming compounds. The lesson PowerPoint and accomapnying worksheet have been designed to cover point 1.25 of the Edexcel GCSE Chemistry specification and also covers that point in the Chemistry section of the Combined Science course The lesson begins with some simple multiple choice questions to check that students can spot the chemical symbol and definition of an element, but more importantly pick out the formula for a compound. Time is taken to go through the explanation of why substances are elements or compounds and specific examples given. A quick understanding check, in the form of a competition called “To COM or NOT TO COM”,is used to check that students can identify elements or compounds from a name or given formula. The remainder of the lesson focuses on naming compounds. Students are challenged to spot a pattern when presented with the names of two compounds, which contain 2 elements only. For both compounds that contain 2 elements or 3 or more, the rules to naming are introduced before examples are shown so that students can visualise how to construct their answer. They are then given an opportunity to apply this to a number of questions in the set tasks. The last part of the lesson moves this forward by looking at how these same rules can be applied when the chemical formula of a compound is given and this is related to another topic as they are challenged to write a word equation containing a range of compounds when presented with the symbol equation. Progress checks are written into the lesson at regular intervals so that students can constantly assess their understanding. Although this is written for Edexcel GCSE students, it is perfectly suitable for use with younger students who are learning about elements, compounds and mixtures and the teacher wants to push them onwards

This lesson describes how the chemical formula of an ionic compound can be deduced using the formulae of the constituent ions. The PowerPoint and accompanying worksheet have been designed to cover point 1.26 of the Edexcel GCSE Chemistry specification and also cover the same point in the Chemistry section of the Combined Science course. This lesson builds on the knowledge acquired in previous lessons when students learnt how to identify the charge of an ion based on the group of the atom. A step by step guide is used to show them how the transfer method can be used to write the formulae for compounds including halides and oxides. Time is taken to introduce the formulae for sulphate, carbonate, hydroxide and nitrate ions and the students are shown how brackets may be needed when writing formulae for compounds containing these ions. Understanding checks in the form of questions and quiz competitions are used to allow the students to assess their progress

This lesson describes an ion as an atom with a positive or negative charge, and explains how cations and anions are formed in ionic compounds. The lesson PowerPoint and accompanying worksheet have been designed to cover points 1.22 - 1.24 of the Edexcel GCSE Chemistry specification and also covers the same points on the Combined Science course. The first part of the lesson focuses on atoms and specifically on getting students to recall that they contain the same number of protons and electrons and this is why they have no overall charge. By ensuring that they are confident with this fact, they will be able to understand why ions have a charge. Students will learn that ions have full outer shells of electrons and this change in the number of this sub-atomic particle leads to the charge. They are shown examples with aluminium and oxide ions and then are challenged to apply this new-found knowledge to a task where they have to explain how group 1, 2, 5 and 7 atoms become ions. The final part of the lesson looks at how ion knowledge can be assessed in a question as they have to recognise the electron configuration of one and describe how many sub-atomic particles are found in different examples. There are regular progress checks throughout the lesson to allow the students to check on their understanding. This lesson has been written for GCSE students but could be used with higher ability KS3 students who are looking to extend their knowledge past basic atomic structure

This lesson describes how to calculate the relative formula mass from simple chemical formulae and for those that include brackets. The PowerPoint and the accompanying worksheet have been designed to cover point 1.43 of the Edexcel GCSE Chemistry specification and also covers that point in the Chemistry section of the Combined Science course. The lesson contains a wide range of tasks, understanding checks and quick quiz competitions to guide students through calculating the relative formula mass for substances with a range of chemical formulae. The relative formula mass is required in a lot of calculations, such as those that involve moles, so it is an important skill to get right. Worked examples are used throughout the lesson to visualise the metho for the students. Initially, students will learn how to calculate the mass from simple formulae before helpful hints are provided for harder formulae such as those that contain a bracket. Students are given the chance to apply their knowledge by proving that mass is conserved in a reaction and this prepares them for an upcoming lesson. This lesson has been written for GCSE students but could be used with higher ability KS3 students in lessons that are looking to push knowledge forward

This fully-resourced lesson describes how to calculate the concentration of solution in grams per decimetres cubed and mol per decimetre cubed. The lesson PowerPoint and accompanying questions which are differentiated have been designed to cover points 1.49 & 5.8 of the Edexcel GCSE Chemistry specification. The lesson begins by introducing students to volumes in decimetres cubed and time is taken to ensure that students are able to convert to this measurement from volumes in centimetres cubed. Moving forwards, students are shown how to calculate the concentration in both units through the use of worked examples and then they are challenged to apply this to a series of exam-style questions which have been differentiated so students of differing abilities can access the work

This lesson describes the differing properties of metals and non-metals and also relates this to their position in the Periodic Table. The lesson PowerPoint has been designed to cover points 1.18, 1.40 & 1.42 of the Edexcel GCSE Chemistry specification and this also covers those same points on the Combined Science course. The lesson contains a range of tasks including guided discussion points and quick quiz competitions which will engage and motivate the students whilst introducing key properties such as malleability and the ability to conduct electricity. Time is also taken to consider where the metallic and non-metallic elements are found in the Periodic Table and a series of progress checks will challenge the students to link together properties with position.

This lesson explains the properties of the fullerenes and focuses on graphene in terms of its structure and bonding. The PowerPoint and the accompanying resources have been designed to cover point 1.38 of the Edexcel GCSE Chemistry specification and also covers that same point on the Combined Science course. The lesson begins by recalling the definition of an allotrope. The students are then introduced to graphene and will begin to understand how this covalent structure is related to graphite and will know the shared properties of these two materials. Time is taken to ensure that students can explain why graphene is able to conduct electricity. Moving forwards, students will meet the family of allotropes known as the fullerenes and will learn some important details about a few of these including C60

This lesson explains the properties of typical covalent simple molecular compounds and introduces diamond and graphite as giant substances. The lesson PowerPoint and accompanying resource have been primarily designed to cover point 1.34 of the Edexcel GCSE Chemistry & Combined Science specifications but also links to points 1.35 - 1.37 where the structure and uses of the giant covalent substances are described. The lesson begins with a quick recap task where students have to recognise a covalent bond from a description and fill the missing part. Moving forwards, they are introduced to the fact that covalent molecules can be simple or giant. They are then presented with a table showing some properties of covalent molecules and having to group them as simple or giant in the short space of time that the table remains displayed on the board. This task challenges their observational skills, something which will again be tested later in the lesson as they study the structure of graphite and diamond. Time is taken to ensure that key details such as the strong covalent bonds in both sets of molecules is understood and that it is the weak intermolecular forces which are actually responsible for the low melting and boiling points. The last part of the lesson introduces diamond and graphite as allotropes of carbon and students will briefly learn why one of these conducts electricity whilst the other doesn’t. If you want a lesson about these allotropes in more detail, then please look for “Diamond and Graphite”. Progress checks have been written into the lesson at regular intervals so that students are constantly assessing their understanding and so misconceptions are quickly identified.

This lesson describes the reactants and products of the Haber Process and then explores and explains why the specific conditions are chosen for this reaction. The PowerPoint and accompanying worksheets have been designed to cover specification point 10.4.1 of the AQA GCSE Chemistry specification. The summary passage which is completed at the end of the lesson has been differentiated two ways. The lesson begins by challenging the students to use a description of the reaction to complete the balanced symbol equation. A quiz competition involving both Chemistry and Maths skills is used to reveal the temperature and pressure which are chosen for this reaction. Students will learn that this only produces a yield of 30% and therefore are encouraged to question why these conditions are chosen. In doing so, they are made to wear two “hats”, so that they consider it from both a Science angle but also a business angle. Their knowledge of reversible reactions and the effect of changing either the temperature or the pressure on the position of the equilibrium are constantly challenged and then checked through a range of progress check questions. As a result of this lesson, students will understand that these conditions are a compromise and be able to explain why.

This lesson describes the meaning of an isotope and explains how to calculate the relative atomic mass using the relative masses and abundance of its isotopes. The PowerPoint and accompanying resources have been designed to cover the detail of points 1.9, 1.11 & 1.12 of the Edexcel GCSE Chemistry & Combined Science specifications. The early topic 1 lessons covered the meaning of the atomic and mass number and the calculation of the number of subatomic particles, and this lesson begins by challenging the recall of this key information. Moving forwards, a quick quiz competition is used to introduce the term “isotope” and then the students have to calculate the number of subatomic particles in K-39, K-40 and K-41 before using their answers to complete a definition about these types of substances. Time is taken to explain how isotopes are represented in standard annotation and the importance of the mass number is emphasised. A series of application questions are used to challenge them to apply their understanding and knowledge and mark schemes are embedded into the PowerPoint to allow the students to self-mark. The remainder of the lesson explains how the existence of isotopes results in some elements having relative atomic masses that are not whole numbers and then explains how these masses can be calculated. Once an example is demonstrated, the students are again given the chance to apply their understanding to a series of questions, and this exam question worksheet has been differentiated two ways

This lesson describes the meaning of an isotope and explains how to calculate the relative atomic mass using the relative masses and abundance of its isotopes. The PowerPoint and accompanying resources are part of the final lesson in a series of 3 lessons have been designed to cover the detail of points 1.1.4, 1.1.5 & 1.1.6 of the AQA GCSE Chemistry & Combined Science specifications. The early topic 1 lessons covered the meaning of the atomic and mass number and the calculation of the number of subatomic particles, and this lesson begins by challenging the recall of this key information. Moving forwards, a quick quiz competition is used to introduce the term “isotope” and then the students have to calculate the number of subatomic particles in K-39, K-40 and K-41 before using their answers to complete a definition about these types of substances. Time is taken to explain how isotopes are represented in standard annotation and the importance of the mass number is emphasised. A series of application questions are used to challenge them to apply their understanding and knowledge and mark schemes are embedded into the PowerPoint to allow the students to self-mark. The remainder of the lesson explains how the existence of isotopes results in some elements having relative atomic masses that are not whole numbers and then explains how these masses can be calculated. Once an example is demonstrated, the students are again given the chance to apply their understanding to a series of questions, and this exam question worksheet has been differentiated two ways

This lesson explains how to calculate the number of protons, neutrons and electrons in atoms and ions when given the atomic and mass numbers. The PowerPoint and accompanying resources are part of the second lesson in a series of 3 lessons which have been designed to cover the content of specification points 1.1.4, 1.1.5 & 1.1.6 of the AQA GCSE Chemistry and Combined Science specifications. The lesson begins by challenging the students to put the chemical symbols for astatine, oxygen, iodine and carbon together to form the word atomic. Time is taken to explain the meaning of the atomic number and to emphasise how the number of protons in the nucleus is unique to atoms of that element. The students will learn that as the number of electrons is always the same as the number of protons in an atom, the atomic number can be used to calculate the numbers of both of these particles. Moving forwards, the mass number is considered and having been given the number of neutrons in a lithium atom, the students are challenged to articulate how the mass number and atomic number were used in this calculation. A series of worked examples are done as a class before the students are given the opportunity to challenge their understanding The remainder of the lesson focuses on ions and how the number of protons, neutrons and electrons are calculated in these substances. Initially, the students are challenged to use their knowledge of the charge of an atom to deduce that ions must have differing numbers of protons and electrons. The standard annotation for ions are introduced and explained and a series of exam questions are then used to check understanding. Mark schemes for each of these final questions is embedded into the PowerPoint and the worksheet has been differentiated two ways

This lesson introduces the alkanes as a group of hydrocarbons and explains how to draw their displayed formula and work out the general formula. The PowerPoint is part of the second lesson in a series of 2 which have been designed to cover point 7.1.1 of the AQA GCSE Chemistry & Combined Science specifications. The students were introduced to crude oil and hydrocarbons in the previous lesson so this one begins by introducing the fact that most of the hydrocarbons in crude oil are alkanes. The students are challenged to recall that covalent bonds will hold hydrogen and carbon together and they will learn that every carbon atom has four covalent bonds. This fact is used in the step by step guide as they are shown how to draw the displayed formula for methane. Moving forwards, a quick competition is used to introduce the next three members of the group in ethane, propane and butane, and the students have to apply their understanding by drawing the formula to find the molecular formula. The general formula for the alkanes is determined and then a series of exam questions will challenge them to apply this to work out numbers of carbon or hydrogen atoms or to write a formula.