This engaging and detailed lesson presentation (43 slides) uses a step by step guide to take students through the important scientific skill of drawing graphs to represent data and address all the misconceptions and misunderstandings that often accompany this topic. The lesson begins by explaining to the students how to decide whether data should be represented on a line graph or a bar chart and a competition called "To BAR or not to BAR" is used to allow them to check their understanding while maintaining motivation. Moving forwards, students are shown a 6 step guide to drawing a line graph. Included along the way are graphs that are wrong and explanations as to why so that students can see what to avoid. There are continuous progress checks and a homework is also included as part of the lesson. This lesson is written for students of all ages who are studying Science.

This is an engaging and practical-based lesson which uses the background idea of a man needing to make crystals for a date to engage students into understanding how the separation methods of filtration and crystallisation work. Like all of the lessons in the separation topic, a lot of the key terms sound similar and are often wrongly used by students. For this reason, time is given in the lesson to ensure that students can use them correctly, especially when describing filtration. In line with the background of the lesson, students are challenged to come up with the apparatus and substances needed to make the crystals. A method is provided so should the teacher choose, students will be able to carry out the practical and produce the copper sulphate crystals. Progress checks are written into the lesson at regular intervals, which question the students on this lesson topic and that of related ones and the final task of the lesson involves an exam question where students have to describe the method and equipment needed to make crystals. This lesson has primarily been written for GCSE students (14 - 16 years in the UK) but is appropriate for younger students who are studying the separation topic

A fully-resourced lesson that uses a range of tasks, understanding checks and quick 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. 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 is a fully-resourced lesson, designed for GCSE students, that lteaches students how to prove that mass is conserved in a chemical reaction and guides them in the explanation of why some reactions do not give equal masses when measured. The lesson begins by introducing the law of the conservation of mass. Students will learn that they can expect questions which challenge them to prove that mass is conserved through the use of the relative formula mass. Therefore, the next section of the lesson focuses on the skills associated with this calculation and looks at more different formulae such as those with brackets. Students are given an opportunity to check their skills before trying to prove mass is conserved in three chemical reactions. All questions have displayed mark schemes so that students can assess their understanding. The rest of the lesson looks at instances of when the mass of the reactants does not equal the mass of the products. A practical method for the decomposition of copper carbonate is provided if the teacher wants to use it, so that students can collect results which show this difference in mass. Discussions are encouraged in order to get students to offer explanations as to why the mass of the products is lower. Once the gas has been identified, students are further challenged to consider apparatus that could be used to collect and record the results to again prove conservation.

This lesson has been designed for GCSE students and looks at the key details of two methods that are used to make ethanol, fermentation and the hydration of ethene. Some students may believe that the sole use of ethanol is for alcoholic drinks so the first part of the lesson uses a quick competition to introduce some additional uses. There are a number of these competitions that run during the lesson, in order to maintain engagement but also to introduce key terms and check on understanding in alternative forms. The details of each of the reactions are discussed and related topics are tested through questions and tasks, such as the students being challenged to write symbol equations and adding state symbols and to remember the identification test for carbon dioxide. The final part of the lesson plays one final competition, which is a battle between all of the students to spot which of the two reactions is being described by a clue.

This lesson has been designed to enable students to recognise the key stages in the formation of the early atmosphere and to also show how today’s atmosphere was formed. The lesson has been primarily designed for GCSE students but is suitable for higher ability younger students who perhaps are studying the Earth and its formation. The lesson begins by checking that the students know the percentages of the different gases found in the modern day atmosphere. Some time is taken to check on their mathematical skills by challenging them to produce a pie chart to represent these different percentages. Students are then asked to predict how they think the percentage of oxygen, carbon dioxide and water vapour would have differed from now to the early atmosphere. The key steps in the formation are then introduced and critical points discussed. Students will learn about the volcanic activity, formation of the oceans and photosynthesis as crucial points in the change to the percentages of those three gases. A number of progress checks are written into the lesson, which check knowledge from this lesson and related topics such as the reaction of acids and gases.

This is a fast-paced lesson that looks at how particle size affects the rate of reaction and challenges the students to carry out a practical to obtain valid results to back up the theory. It is a fully-resourced lesson that consists of an engaging lesson presentation (19 slides) and a calculation worksheet which is differentiated two ways to enable those students who find the maths hard to have a way to access the learning. Students are guided through a method of calculating the surface area and volume of the object and calculating the surface area to volume ratio. Using the answers to their calculations, they will complete a summary passage which explains why having more exposed reacting particles leads to an increased rate of reaction. Students will then carry out a practical where they have to determine which cube of jelly to use to make jelly the fastest in order to test their summary passage is valid. This lesson has been designed for GCSE students but could be used with younger students looking at chemical reactions and investigating the factors that affect the rate.

A thought-provoking lesson which explores why certain conditions are chosen for reversible reactions. Throughout this lesson, students are challenged to think about the topic in three ways. Of course, they have to consider the chosen conditions from a Scientific angle by knowing how temperature and pressure affect the position of the equilibrium. They must also think about the business (and health) side of the argument by recognising that increased pressures are both dangerous and expensive. Finally, they are taught recognise how the chosen conditions are in fact a compromise which has taken both the Science and business into account. Students are guided through the choice of conditions for the production of methanol so that they can apply their knowledge to the production of ammonia by the Haber process. This lesson has been designed for GCSE students.

This lesson has been written with the aim of engaging students in the topic of simple and giant covalent molecules, as this is a topic which is often considered to be boring or is brushed over. A variety of tasks have been used to maintain the interest whilst ensuring that they key details and Science are known and understood. 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 has been written for GCSE students (14 - 16 years of age in the UK)