This is a detailed and engaging lesson that looks at how molecules move between areas of differing concentrations by diffusion and then explores how this occurs across cell membranes and focuses on the alveoli. The lesson begins by using a step by step format to write the definition for diffusion so that key terms such as concentration gradient are understood. Students will be introduced to this as a passive process so that they can understand how active transport differs when this is met in another lesson. Progress checks are written into the lesson at regular intervals so that students can assess their understanding against a displayed answer. Moving forwards, the lesson focuses on diffusion across cell membranes and uses the example of the exchange surface of the alveoli and blood capillaries to explore the different features which act to increase the rate of diffusion. The final part of the lesson briefly looks at how the villi in the small intestine increase the rate of diffusion. This lesson has been written for GCSE aged students. If you’re looking for a lesson on this topic but for older students, then my alternative upload “Simple diffusion” will be more suitable

This lesson describes the uses and implications of pre-implantation genetic diagnosis, amniocentesis and chorionic villus sampling. The lesson PowerPoint and accompanying worksheets have been primarily designed to cover point 2.17 of the Edexcel International A-level Biology specification but there are regular checks of their knowledge of the content of topic 2, where topics including monohybrid inheritance and cystic fibrosis are tested. The lesson begins by challenging them to use this prior knowledge of topic 2 to identify the letters in the abbreviations PGD and CVS. The involvement of IVF to obtain the embryos (or oocytes) is then discussed and a series of exam-style questions are used to get them to understand how this method screens embryos prior to implantation, so that those identified as having genetic diseases or being carriers are not inserted into the female’s uterus. Mark schemes for all of the questions included in this lesson are embedded into the PowerPoint so students can constantly assess their progress. Moving forwards, Down syndrome (trisomy 21) is used as an example of a chromosomal abnormality that can be tested for using CVS or amniocentesis. Time is taken to describe the key details of both of these procedures so students have a clear understanding of the implications and the invasiveness to the female being tested. The link between amniocentesis and an increased risk of miscarriage is considered and the results of a 2006 study are used to challenge them on their data skills.

This is a detailed lesson which looks at the topic of reaction times and guides students through calculating a reaction time using the results of the well known ruler-drop test. In addition, students will see how reaction times can be applied in athletics but also in the calculation of the thinking distance for drivers. The lesson includes an engaging lesson presentation (32 slides) and a student task worksheet. The lesson begins by introducing the key term, reaction time, and teaching students that the average reaction time is 0.2 seconds. Moving forwards, a step by step guide is used to show the students how to take the value for distance travelled by a ruler in the drop test and use the equations of motion and change in velocity equation to calculate the reaction time. There is a large mathematical element to the lesson which challenges the students ability to rearrange formula, convert between units and leave answers to a specified number of significant figures. The answers and methods in obtaining these are always displayed at the end of each task so that the students can assess their understanding and recognise where errors were made if any were. Students will have to follow the provided method to obtain 5 results in the ruler drop test and ultimately find out their own reaction time. The remainder of the lesson looks at how the thinking distance at different speeds can be calculated. This lesson has been written for GCSE students due to the high maths content but could be used with younger students of high ability.

This fully-resourced lesson explores the inheritance of sex-linked diseases in humans and then challenges the students to apply their knowledge to examples in other animals. The detailed PowerPoint and associated differentiated resources have been designed to cover the part of point 6.1.2 (b[i]) of the OCR A-level Biology A specification which states that students should be able to demonstrate and apply their knowledge and understanding of genetic diagrams which include sex-linkage. Key genetic terminology is used throughout and the lesson begins with a check on their ability to identify the definition of homologous chromosomes. Students will recall that the sex chromosomes are not fully homologous and that the smaller Y chromosome lacks some of the genes that are found on the X. This leads into one of the numerous discussion points, where students are encouraged to consider whether females or males are more likely to suffer from sex-linked diseases. In terms of humans, the lesson focuses on haemophilia and red-green colour blindness and a step-by-step guide is used to demonstrate how these specific genetic diagrams should be constructed and how the phenotypes should then be interpreted. The final tasks of the lesson challenge the students to carry out a dihybrid cross that involves a sex-linked disease and an autosomal disease before applying their knowledge to a question about chickens and how the rate of feather production in chicks can be used to determine gender. All of the tasks are differentiated so that students of differing abilities can access the work and all exam questions have fully-explained, visual markschemes to allow them to assess their progress and address any misconceptions.

An engaging lesson presentation (39 slides) which explores how cells differentiate in order to specialise to become more effective at carrying out a particular function. This lesson focuses on five cells - red blood cells, sperm cells, fat cells, ciliated cells and palisade cells. The lesson begins by challenging the mathematical skills of the students as they have to convert the number 37 trillion into standard form. Students will learn that although all of the cells found in a human would be eukaryotic animal cells, they wouldn’t all be the same. They are introduced to the key term differentiation through a quiz competition and time is taken to ensure that students understand how this process leads to specialisation. The remainder of the lesson concentrates on looking at the function and features of the five cells. Quiz competitions are used throughout to maintain engagement whilst ample time is given to student discussion where they are challenged to consider why a cell would have specialised in such a way. Key terminology is consistently used so that students are not caught off guard in an exam question when this specialist language is used. Regular progress checks are written into 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 on the topic of cells.

A resourced lesson which looks at the organisation of the human nervous system and explores how these structures are involved in nervous reactions. The lesson includes an engaging lesson presentation (27 slides) and an associated worksheet with an understanding check. The lesson begins by looking at different examples of stimuli and therefore introducing the key term, receptors, as structures which detect these changes in the environment. Moving forwards, a quiz competition is used to introduce the students to the abbreviations CNS and PNS and students will learn the structures that are found in these parts. At this stage of the lesson, a quick understanding check is written into the lesson to see whether students know the functions of each of the structures and check whether they can order them correctly from stimuli to effectors. Students will meet the term synapse and be taught that the conduction across these gaps is slow so that this knowledge can be applied in future lessons on reflexes. The remainder of the lesson challenges the students to apply their new-found knowledge in ordering an example of a nervous reaction.

A fully-resourced lesson which looks at how auxins are involved in the response to the stimuli and gravity. The lesson includes an engaging lesson presentation (29 slides) and associated worksheets which have been differentiated. The lesson begins by challenging students to consider the different stimuli that a plant will respond to. There is focus throughout the lesson on the use of key terminology and students will start immediately by meeting the different types of tropisms. A quick competition is used to introduce the students to auxins and the key details of these chemicals are discussed. They will see how they are produced in the tips of shoots and roots and cause cell elongation in the shoots. A summary task is used to get the students to explain how a plant grow towards a light source. The next task challenges the students to apply their knowledge as a range of experimental data is shown to them and they have to predict how the plant would respond and explain - this task has been differentiated two ways so those students who need extra assistance can access the learning. The final part of the lesson looks at gravitropism and all of the learning is brought together to explain how the shoots grow away and the roots towards. This lesson has been written for GCSE students.

An engaging lesson presentation (45 slides) that uses a combination of exam questions, quick tasks and quiz competitions to help the students to assess their understanding of the topics found within unit P6 (Waves) of the AQA GCSE Combined Science specification (specification point P6.6). The topics that are tested within the lesson include: Longitudinal and transverse waves Properties of waves Types of EM waves Properties and applications of EM waves Students will be engaged through the numerous activities including quiz rounds like “Tell EM the word” and “Take the HOTSEAT” whilst crucially being able to recognise those areas which need further attention

An engaging lesson presentation (59 slides) and associated worksheets that uses a combination of exam questions, quick tasks and quiz competitions to help the students to assess their understanding of the topics found within unit B2 (Scaling up) of the OCR Gateway A GCSE Biology specification The topics that are tested within the lesson include: Diffusion Osmosis Active transport Exchange and transport Circulatory systems Heart and blood Plant transport systems Transpiration Students will be engaged through the numerous activities including quiz rounds like “Where’s LENNY?" whilst crucially being able to recognise those areas which need further attention

An engaging lesson presentation (73 slides) and associated worksheets that uses a combination of exam questions, quick tasks and quiz competitions to help the students to assess their understanding of the topics found within TOPIC 1 (Atomic structure and the Periodic Table) of the AQA GCSE Chemistry specification (specification unit C4.1). The topics that are tested within the lesson include: Mixtures Development of the model of the atom The subatomic particles Electronic structure The periodic table Group 0 Group 1 Group 7 The transition metals Students will be engaged through the numerous activities including quiz rounds like “UNLOCK the safe" whilst crucially being able to recognise those areas which need further attention

An engaging lesson presentation (64 slides) and associated worksheets that uses a combination of exam questions, quick tasks and quiz competitions to help the students to assess their understanding of the topics found within TOPIC 8 (Chemical analysis) of the AQA GCSE Chemistry specification (specification point C4.8) The topics that are tested within the lesson include: Pure substances Chromatography Identification of common gases Identification of ions Students will be engaged through the numerous activities including quiz rounds like “Take the CHROMATOGRAPHY hotseat” whilst crucially being able to recognise those areas which need further attention

This lesson describes the processes that take place during interphase, mitosis and cytokinesis and outlines how checkpoints regulate the cell cycle. The PowerPoint and accompanying resources have been designed to cover points 2.1.6 (a & b) of the OCR A-level Biology specification and prepares the students for the upcoming lessons on the main stages of mitosis and its significance in life cycles The students were introduced to the cell cycle at GCSE so this lesson has been planned to build on that knowledge and to emphasise that the M phase which includes mitosis (nuclear division) only occupies a small part of the cycle. The students will learn that interphase is the main stage and that this is split into three phases, G1, S and G2. A range of tasks which include exam-style questions, guided discussion points and quick quiz competitions are used to introduce key terms and values and to describe the main processes that occur in a very specific order. There is also a focus on the checkpoints, such as the restriction point that occurs before the S phase to ensure that the cell is ready for DNA replication. Extra time is taken to ensure that key terminology is included and understood, such as sister chromatid and centromere, and this focus helps to show how it is possible for genetically identical daughter cells to be formed at the end of the cycle. Important details of mitosis are introduced so students are ready for the next lesson, before the differences in cytokinesis in animal and plant cells are described.

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 fully-resourced lesson which looks at the structure of the human heart and its associated vessels and ensures that students know the journey which blood takes through this organ. The lesson includes an engaging lesson presentation (25 slides), a diagram to label and a worksheet to summarise the journey. The lesson begins with a bit of fun as students see the script to part of an episode from Friends. Students will recognise the alternative definition of the heart and ultimately recall that the function of this organ is to pump blood around the body. Moving forwards, the main task of the lesson involves labelling the four chambers and the blood vessels which bring blood towards and away from the heart. Students are given useful hints along the way to enable them to discover the answers rather than simply being given a finished diagram. Time is taken to look at the valves and discuss their function so that students can understand this role when they encounter them in veins. The lesson concludes with one final task that challenges the students to detail the journey of blood through the heart. There are regular progress checks throughout the lesson to allow the students to check on their understanding. As always, the lesson finishes with a slide containing advanced terminology so that students who have aspirations to take A-level Biology can extend and deepen their knowledge

This is an engaging REVISION lesson which uses a range of exam questions, understanding checks, quick tasks and quiz competitions to enable students to assess their understanding of the content within topic 2 (Electricity) of the AQA GCSE Physics (8463) specification. The specification points that are covered in this revision lesson include: Standard circuit diagram symbols Current, resistance and potential difference Resistors Series and parallel circuits Direct and alternating potential difference Mains electricity Power Static charge The students will thoroughly enjoy the range of activities, which include quiz competitions such as “GRAFT over these GRAPHS” where they have to compete to be the 1st to recognise one of the graphs associated with the resistors whilst all the time evaluating and assessing which areas of this topic will need their further attention. This lesson can be used as revision resource at the end of the topic or in the lead up to mocks or the actual GCSE exams

This lesson explains the effects of temperature increases on enzyme activity and describes how to calculate the temperature coefficient. The PowerPoint and the accompanying resource are part of the second lesson in a series of 3, which cover the content detailed in point 2.1.4 (d) [i] of the OCR A-level Biology A specification and this lesson has been specifically planned to tie in with an earlier lesson covering 2.1.4 (a, b & c) where the roles and mechanism of action of enzymes were introduced. The lesson begins by challenging the students to recognise optimum as a key term from its 6 synonyms that are shown on the board. Time is taken to ensure that the students understand that the optimum temperature is the temperature at which the most enzyme-product complexes are produced per second and therefore the temperature at which the rate of an enzyme-controlled reaction works at its maximum. The optimum temperatures of DNA polymerase in humans and in a thermophilic bacteria and RUBISCO in a tomato plant are used to demonstrate how different enzymes have different optimum temperatures and the roles of the latter two in the PCR and photosynthesis are briefly described to prepare students for these lessons in modules 6 and 5. Moving forwards, the next part of the lesson focuses on enzyme activity at temperatures below the optimum and at temperatures above the optimum. Students will understand that increasing the temperature increases the kinetic energy of the enzyme and substrate molecules, and this increases the likelihood of successful collisions and the production of enzyme-substrate and enzyme-product complexes. When considering the effect of increasing the temperature above the optimum, continual references are made to the previous lesson and the control of the shape of the active site by the tertiary structure. Students will be able to describe how the hydrogen and ionic bonds in the tertiary structure are broken by the vibrations associated with higher temperatures and are challenged to complete the graph to show how the rate of reaction decreases to 0 when the enzyme has denatured. The final part of the lesson introduces the Q10 temperature coefficient and students are challenged to apply this formula to calculate the value for a chemical reaction and a metabolic reaction to determine that enzyme-catalysed reactions have higher rates of reaction Please note that this lesson has been designed specifically to explain the relationship between the change in temperature and the rate of enzyme activity in a reaction and not the practical skills that is part of a lesson covering specification point 2.1.4 (d) [ii]

A fully resourced lesson presentation (53 slides) and associated worksheet that uses a combination of exam questions, understanding checks, quick tasks and a quiz competition to help the students to assess their understanding of the topics found within TOPIC 5 (Energy changes) of the AQA GCSE Chemistry specification (specification point C4.5). The lesson includes useful hints and tips to encourage success in assessments. For example, students are shown how to use the energy change in a chemical reaction to work out if it is an endothermic or exothermic reaction. The topics that are tested within the lesson include: Endothermic and exothermic reactions Reaction profiles Calculating energy changes in reactions Fuel cells Students will be engaged through the numerous activities including a summary round called “E NUMBERS” which requires them to use all of their knowledge to work out the type of reactions that are shown.

This is an engaging revision lesson which uses a range of exam questions, understanding checks, quiz tasks and quiz competitions to enable students to assess their understanding of the content within topic 6 (Chemical energetics) of the Cambridge IGCSE Chemistry (0620) specification. The lesson covers the content in both the core and supplement sections of the specification and therefore can be used with students who will be taking the extended papers as well as the core papers. The specification points that are covered in this revision lesson include: CORE Describe the meaning of exothermic and endothermic reactions Interpret energy level diagrams showing exothermic and endothermic reactions Describe the release of heat energy by burning fuels State the use of hydrogen as a fuel SUPPLEMENT Describe bond breaking as an endothermic process and bond forming as an exothermic process Draw and label energy level diagrams for exothermic and endothermic reactions using data provided Calculate the energy of a reaction using bond energies Describe the use of hydrogen as a fuel reacting with oxygen to generate electricity in a fuel cell. The students will thoroughly enjoy the range of activities, which include quiz competitions such as “E NUMBERS” where they have to recognise the differences between endothermic and exothermic reactions whilst crucially being able to recognise the areas of this topic which need their further attention. This lesson can be used as revision resource at the end of the topic or in the lead up to mocks or the actual GCSE exams

A fully resourced lesson, which includes differentiated worksheets, and guides the students through the process of extracting aluminium. There are close links throughout the lesson to the reactivity series and electrolysis so that the students are able to understand how the knowledge of all of these is brought together. Students will meet cryolite and recognise why this is used in the process and will finish off by writing half equations to show the products at the electrodes. This lesson has been designed for GCSE students (14 - 16 year olds in the UK)

A fully-resourced lesson that looks at a number of the allotropes of carbon which need to be known for GCSE Science. The lesson includes an engaging lesson presentation (40 slides) and associated worksheets. The lesson begins by recalling the definition of an allotrope. Students are then introduced to graphene and will understand how this is related to graphite and know the properties of these two materials that are shared. 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 see some important details about a few of these. This lesson has been written for students studying GCSE (14 - 16 year olds in the UK).