A resourced lesson which looks at a number of examples of biological polymers. The lesson includes an engaging lesson presentation (40 slides) and a couple of worksheets to be used in the understanding check task. The starter activity challenges the students to use their Chemistry knowledge to come up with the abbreviation DNA. They will learn the key details of this polynucleotide and then time and focus is given to the nitrogenous bases and how they bond between the two strands. Moving forwards, students will be shown the next biological polymer that is a polypeptide. They are briefly shown how to draw a block diagram to represent the chain of amino acids. The final polymer are carbohydrates and students will learn how glycogen, starch and cellulose are formed from glucose monomers. Regular progress checks are written into the lesson at regular intervals to allow the students to check their understanding and ask questions. This lesson has been written for GCSE students

An informative lesson presentation (44 slides) that looks at the work of the key Scientists involved in the development of the atomic model. Dalton, Thomson, Rutherford and Bohr were four men whose work has led to the changes in the atomic model over the years and this lesson looks at parts of each of their work. There is a focus on Rutherford’s work with the alpha particles and students are challenged to draw conclusions based on the deflections they are shown. There is lots of time written into the lesson for consolidation and regular progress checks ensure that students have the opportunity to assess their understanding. This lesson has been written for GCSE students but could be used with KS3 students who perhaps are carrying out a project on the atom and want to add detail to their work

A fully-resourced lesson which looks at speed and velocity as scalar and vector quantities and then guides students through a range of questions which challenge them to calculate both of these forms of motion. The lesson includes an engaging lesson presentation (44 slides) and differentiated worksheets containing questions. The lesson begins by introducing the terms magnitude and direction so that students can learn how scalar and vector quantities differ. Students will learn that speed is a scalar quantity and velocity is a vector quantity and then be questioned through a crossroads scenario to understand how speed can stay the same but as soon as an object changes direction, the velocity changes. Moving forwards, the students are given the equation to calculate speed and a few simple questions are worked through before they have to do a series of their own questions to find the average speeds for walking, running and cycling. A pair of more difficult speed questions are then attempted which challenge the students to convert from metres per seconds to miles per hour and to calculate the speed of a bicycle by calculating the distance travelled by the sensor on the wheel. This task is differentiated so that students who need some assistance will still be able to access the work. A quiz competition is then used to introduce students to the range of equations which contain velocity and then having been given them, they have to rearrange the formula to make velocity the subject and apply to some further questions. The final task of the lesson brings all the work together in one final competition where students have to use their new-found knowledge of speed and velocity to get TEAM POINTS. Progress checks have been written into the lesson at regular intervals to allow the students to check their understanding and any misconceptions to be addressed immediately. This lesson has been written for GCSE students and links between the other topics on the curriculum but could be used with KS3 students who are finding the topic of speed too simple and are needing a challenge

A fully-resourced lesson which looks at the chemical reaction of cracking and the conditions that are needed for this reaction on both an industrial scale and in a laboratory. The lesson includes an engaging lesson presentation (33 slides) and an associated worksheet containing questions for a progress check. The lesson begins by challenging the students to use their knowledge of alkanes and a given example to work out the name of a 6, 7 and 8 carbon alkane. Students need to be able to name the alkanes and alkenes in order to understand the products of a cracking reaction. A number of quiz competitions are used to introduce both the name of the reaction but also the temperature that is needed when it is carried out on an industrial scale. Students will then be shown a diagram of a cracking experiment in a laboratory so they can discover that a catalyst is also needed. Students will learn, either through carrying out the experiment or through the informative slide, that the product of a cracking reaction is a smaller alkane molecule and a smaller alkene molecule. Time is taken to go back over the meaning of saturated and unsaturated and once the students have been introduced to bromine water, they are challenged to work out what the respective reactions will be when it is added to an alkane and an alkene. The remainder of the lesson focuses on writing word and chemical symbol equations for a cracking reaction. Students will be shown how the second product of a reaction can be worked out when the reactant and first product are provided and then they challenge themselves by trying to write three equations. Understanding checks are written into the lesson at regular places to allow the students to check on their understanding. This lesson has been designed for GCSE students.

A resourced lesson which looks at the key details of a titration to enable students to generate results which could be used in a titration calculation. The lesson includes an engaging lesson presentation (29 slides) and an associated worksheet. The lesson begins with a spot of fun as students are challenged to read the script of a scene from Friends to identify a neutralisation reaction. Students will learn that a method called a titration can use the results of an acid-base neutralisation to work out the concentration of an unknown. Students will learn the names of the equipment involved through a quiz competition and will then be shown how to set up a table to collect the results. Key terms such as titre, rough and end-point are explained. The lesson finishes with one further round of the competition called “Take the HOTSEAT” so that the knowledge of the key terminology from today’s lesson can be checked. The lesson has been designed with regular progress checks throughout so that students can check their understanding. This lesson has been designed for GCSE students.

A concise lesson presentation (21 slides) which uses a range of methods to allow students to discover how to draw dot and cross diagrams for covalent structures. The lesson begins by challenging the students to recall their knowledge of electronic structure to show the outer shell of two specified atoms. They will then see how it is possible for both of these atoms to get full outer shells by sharing as happens in this type of bonding. A few more examples are used to consolidate this understanding before quick competition is used to check the understanding so far. Moving forwards, a step by step guide shows students how to draw dot and cross diagrams using the same techniques as was utilised with the hulas. This lesson has been written for GCSE students but could be used with higher ability KS3 students.

An engaging lesson presentation (46 slides) which looks at the fractional distillation of crude oil and focuses on the properties of the different fractions. The aim at the start of the lesson is to ensure that students understand that this process can be broken down into evaporation followed by condensation. Moving forwards, a fun competition is used to introduce the students to the names of some of the important fractions that are produced by this process. At the same time, they will learn the relative position that each fraction condenses on the fractionating column and will be taught that they need to know this position with relation to the other fractions. Students will learn that the fractions have differing properties depending on where they condense and they are challenged to compare fractions by viscosity, length of hydrocarbon and boiling point. 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.

A concise lesson presentation (19 slides) which looks at meaning of the key term, polymers, and briefly explores addition and condensation polymers. The lesson begins with a fun exercise to enable students to come up with the word polymers so that they can be introduced to the definition and then relate this to another term, monomers. A quiz competition is used to introduce addition and condensation polymers. Students are shown the displayed formulae and names of a few addition polymers and then challenged to use this to name and draw some others. They will then learn how DNA is an example of a condensation polymer. A set homework is included in the lesson which gets students to research thermosetting and thermosoftening polymers

A fully-resourced lesson which explores how ions are formed from atoms. The lesson includes an engaging lesson presentation (33 slides) and an associated worksheet to be used during an understanding check. The first part of the lesson focuses on atoms and specifically on getting students to recall that they contains the same number of protons and electrons and this is why they have no 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 oxygen and then 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

An informative lesson presentation (24 slides) that looks at the relative size of the nanoparticles and explains why they are so effective for a range of purposes. The lesson begins by looking at exactly how small nanoparticles are and ensures that students can recognise this size in a range of ways, including standard form. Moving forwards, in order to help students to understand why these nanoparticles are being used in a lot of different ways, students are introduced to bulk materials. Included in the remainder of the lesson is calculating the surface area to volume ratio so this can be used as a comparison point. There are regular progress checks throughout the lesson so that students can assess their understanding. This lesson has been written for GCSE students.

An engaging and informative lesson presentation (43 slides) that shows students how to write accurate chemical formulae for ionic compounds. In order to write accurate chemical formulae, students need to know the charges of the ions involved. For this reason, the lesson begins by reminding students how they can use the Periodic Table to work out the charge of the charged atoms. Students are shown how they can use these ion charges to write the formula and then are given the opportunity to apply this to a number of examples. Moving forwards, students are shown how some formulae need to contain brackets. The lesson finishes with a competition called “Ye Olde Chemical Formula Shop” where students get points if they are the first to work out the formula of a given substance. This lesson has been written for GCSE students.

A fully-resourced lesson which guides students through drawing, writing and recognising the electronic configurations of atoms and ions. The lesson includes an engaging lesson presentation (33 slides), an associated worksheet and a competition worksheet. The lesson begins by introducing the students to the number of electrons that can be held on the first three electron shells. They are then shown how to draw an electronic configuration and write this in brackets form. Students are given the opportunity to apply this knowledge by drawing the configuration of first 20 elements of the Periodic Table. Moving forwards, students are guided to enable them to discover how the electron configuration is linked to the position of an atom in the Periodic Table. The remainder of the lesson focuses on ions and how the configuration of these substances can be recognised. Some time is taken to explain how ions are formed from atoms and the lesson finishes with a competition which challenges students to identify atoms or ions from their configurations to form a word. There are regular progress checks throughout the lesson to allow the students to check on their understanding and a range of quiz competitions to maintain engagement. This lesson has been written for GCSE students but could be used with younger students, especially the initial part of the lesson on atoms and the link to the Periodic Table

A fully-resourced lesson which guides students through using moles to calculate the mass of a substance in a reaction. The lesson includes a detailed lesson presentation (22 slides) and associated worksheets which are used to check the skills and understanding of the students. The lesson begins by introducing the students to the three steps involved in a calculating mass question. These skills include calculating the relative formula mass and identifying molar ratios in equations to calculate amounts so time is taken to recap on how this is done before students are given the opportunity to try some progress check questions. A worked example brings these three steps together to guide the students to the final answer. The final task involves 4 questions where students are challenged to apply their new-found knowledge. This lesson has been written for GCSE students (14 - 16 year olds in the UK)

A fully-resourced lesson which looks at the gaseous reversible reaction known as the Haber Process and then explores and explains why the specific conditions are chosen for this reaction. The lesson includes a detailed lesson presentation (29 slides) and associated worksheets which are differentiated. 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 has been designed for GCSE students (14 - 16 year olds in the UK).

A resourced lesson which guides students through the method of writing word equations for a range of different chemical reactions. The lesson includes an engaging and informative lesson presentation (33 slides) and an associated worksheet containing questions. The lesson begins by reminding students of the form which word equations take, with the reactants chemically changing into the products. Moving forwards, time is taken to show students how to work out the name of a compound that contains either 2 or 3 elements. This moves nicely into the reaction of acids and how to name the salt that is produced. Students are shown the general formula for the reactions of acids with a metal, a metal carbonate and a metal oxide or hydroxide so that they can form word equations for each of these reactions in the progress check task. The final section of the lesson introduces reversible reactions to the students and shows them the symbol that is used in these word equations to replace the arrow. There are regular progress checks throughout the lesson to allow the students to check on their understanding and thorough explanations of the required answers. This lesson has been written for GCSE students but is perfectly suitable for KS3 students too.

A fully-resourced lesson which uses a step-by-step guide to show students how to write fully balanced symbol equations. The lesson includes an engaging lesson presentation (38 slides) and associated worksheets containing questions which iaredifferentiated. The lesson begins by talking the students through the three steps involved in writing a chemical symbol equation. The first step involves writing in the formula for the elements. Students are introduced to the term, diatomic, and shown the 8 molecules that have to be written as a pair of atoms. Moving forwards, students are shown how to write chemical formulae for ionic compounds. They are reminded of how to use the group of the Periodic Table to work out the ion charge and how this is crucial when writing the formula. They are also shown how to write formulae which include brackets which is necessary when the charged molecules are involved. Finally, students are reminded of the rules of balancing symbol equations. There are progress checks at each stage so that students can assess their understanding and any misconceptions can be be addressed immediately. Time is taken to talk about state symbols, in case the exam question requires these to be included in the equation. The final section of the lesson involves students bringing their new-found skills together to write symbol equations for a range of reactions, including a neutralisation and reversible reaction. This task is differentiated so that students who need a little bit of assistance can still access the work. This lesson has been written for GCSE students (14-16 year olds in the UK)

A fully-resourced lesson which looks at how decomposers are involved with the process of decay. The lesson includes an engaging and detailed lesson presentation (31 slides) and an associated differentiated worksheets. The lesson begins by displaying the definitions for decomposers and detritivores and challenging students to use their bingo cards to see if they can work out the words which are being described. Students will learn how these two types of organisms work together to break down matter. Moving forwards, a worked example is used to guide students through how to calculate the rate of decay from a range of different data types. Students will be challenged to act like a travel agent for decomposers to come up with the different conditions that they require. Finally, they have to bring all of the new-found knowledge together to answer a range of summary questions. These questions are differentiated two ways so that differing abilities can access the work. 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 (14 - 16 year olds in the UK)

A thought-provoking lesson presentation (34 slides) that looks at each of the stages in the development of drugs and considers the potential issues that arise at each of the stages. The lesson begins by ensuring that the students know the scientific definition of a drug and then they will be told how much is spent by the NHS alone each year on medicinal drugs so they can recognise the importance of this topic. Moving forwards, each stage in the development is considered in the appropriate detail. Students are challenged to consider some stages from both a scientific angle and a business angle so they can understand why certain animals are chosen for the testing. Key terms such as placebo and double blind trial are introduced and discussion time is written into the lesson so that insightful questions can be posed by all. 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 KS3 students who might be carrying out research or a project on the topic of drugs.

A fully-resourced lesson which looks at the saturated hydrocarbons known as the alkanes and focuses on their structure and reactions. The lesson includes an engaging lesson presentation (38 slides) and an associated worksheet which is differentiated. The lesson begins with the introduction of the name of this group and then a step-by-step guide is used to show students how to draw the displayed formula. Once the first four have been drawn, students are shown how to calculate the general formula for the alkenes and then challenged to do the same for the alkanes. Moving forwards, students will meet the key term, saturated, and time is taken to ensure that the meaning of this word is understood in the context of this lesson. Once they have been introduced to bromine water, students are challenged to work out what will happen when this substance is added to an alkane and they have to explain their answer. The remainder of the lesson looks at the complete and incomplete combustion of the alkanes, focusing on the different products of these reactions and specifically the problems associated with carbon monoxide. There are regular progress checks throughout the lesson to allow the students to check on their understanding.

A concise, engaging lesson presentation (22 slides) which looks at the different responses of the body as a result of adrenaline release. In line with the actions of adrenaline, the lesson begins with a range of quiz competitions to introduce key terms and responses to the students. Once the students know that it causes both the breathing and heart rate to increase, they are challenged to complete a passage which brings this information together to explain how the increased respiration rate is related to the fight or flight tag line. Moving forwards, students will be introduced to the meaning of the term vasodilation and then asked to consider which organs will need extra blood flow during times of stress and conversely, which tissues can have blood directed away from them. The lesson finishes by looking at how a negative feedback loop is used as the final control to ensure that energy resources are not wasted during times when there is no stress.