Science Curriculum Overview
Aim
Here at ϳԹվ, we aim to securely equip all of our students for life beyond school as successful, confident, responsible and respectful citizens. We believe that education provides the key to social mobility and our curriculum is designed to build strong foundations in the knowledge, understanding and skills which lead to academic and personal success. We want our students to enjoy the challenges that learning offers.
Our aims are underpinned by a culture of high aspirations. Through developing positive relationships, we work towards every individual having a strong belief in their own abilities so that they work hard, build resilience and achieve their very best.
Intent
We aim to provide a high-quality science education that provides the foundations for understanding the world through the disciplines of biology, chemistry and physics. Science is changing our lives and is vital to the world’s future prosperity, and all students should be taught essential aspects of foundational knowledge, methods, processes and uses of science. Through building up a body of core knowledge and concepts, pupils are encouraged to recognise the power of rational explanation and develop a sense of excitement and curiosity about natural phenomena. They will be encouraged to understand how science can be used to explain what is occurring, predict how things will behave, and analyse causes.
The curriculum aims to ensure that knowledge is taught to be remembered, not encountered. The curriculum embraces learning from cognitive science about memory, forgetting and the power of retrieval practice. Knowledge for each unit is planned vertically and horizontally, giving thought to the optimum knowledge sequence for building secure schema.
The curriculum aims for pupils to:
- Develop scientific knowledge through the disciplines of biology, chemistry and physics;
- Develop understanding of the nature, processes and methods of science through different types of scientific enquiry that help them answer scientific questions about the world around them;
- Develop and learn to apply observational, practical, modelling, enquiry, problem solving and mathematical skills, both in the laboratory, in the field and other environments;
- Develop their ability to evaluate claims based on science through critical analysis of the methodology, evidence and conclusions, both qualitatively and quantitatively.
Throughout our programmes of study, every attempt is made to make explicit links to careers and the world of work. In addition to subject specific links, we aim to explicitly reinforce the skills and aptitudes which support employers say are important in the workplace;
- Resilience (Aiming High Staying Positive Learning from Mistakes)
- Collaboration (Teamwork Leadership Communication)
- Creativity (Originality, Problem Solving, Independent Study)
The British values of democracy, the rule of law, individual liberty, and mutual respect of those with different faiths and beliefs are taught explicitly and reinforced in the way in which the school operates.
Sequence and structure
Our curriculum is split in to Key Stage 3 (years 7, 8 and 9) and Key Stage 4 (years 10 and 11). Our longer school day and generous allocation of curriculum time ensures a strong foundation of knowledge and skills for success at KS4.
Year 7 KS3 Curriculum
Click here to view the Year 7 Biology curriculum intent for 2023-2024.
Click here to view the Year 7 Chemistry curriculum intent for2023-2024.
Click here to view the Year 7 Physics curriculum intent for 2023-2024.
We know that students who read well achieve well. As such all subject areas are committed to providing regular opportunities to read extensively. We provide regular opportunities for students to read for pleasure and to receive small group interventions if their reading skills are lower than we would expect.
Year 8 KS3 Curriculum
Click here to view the Year 8 Chemistry curriculum intent for 2023-2024.
Click here to view the Year 8 Physics curriculum intent for 2023-2024.
We know that students who read well achieve well. As such all subject areas are committed to providing regular opportunities to read extensively. We provide regular opportunities for students to read for pleasure and to receive small group interventions if their reading skills are lower than we would expect.
Year 9 KS3 Curriculum
Click here to view the Year 9 Physics curriculum intent for 2023-2024.
We know that students who read well achieve well. As such all subject areas are committed to providing regular opportunities to read extensively. We provide regular opportunities for students to read for pleasure and to receive small group interventions if their reading skills are lower than we would expect.
Year 10 KS4 Curriculum
Our Key Stage 4 Curriculum
At Key Stage 4 students follow the AQA Exam board, taking either Separate Science or Combined Science: Trilogy.
KS 4 Half Term 1 Half Term 2 Half Term 3 Half Term 4 Half Term 5 Half Term 6 Year 10 Biology : Infection and response Pathogens are microorganisms such as viruses and bacteria that cause infectious diseases in animals and plants. They depend on their host to provide the conditions and nutrients that they need to grow and reproduce. They frequently produce toxins that damage tissues and make us feel ill. This section will explore how we can avoid diseases by reducing contact with them, as well as how the body uses barriers against pathogens.
Chemistry: Chemical changesUnderstanding of chemical changes when people began experimenting with chemical reactions in a systematic way and organizing their results logically. Knowing about these different chemical changes meant that scientists could begin to predict exactly what new substances would be formed and use this knowledge to develop a wide range of different materials and processes. It also helped biochemists to understand the complex reactions that take place in living organisms. The extraction of important resources from the earth makes use of the way that some elements and compounds react with each other and how easily they can be ‘pulled apart’.
Physics: Electricity Electric charge is a fundamental property of matter everywhere. Understanding the difference in the microstructure of conductors, semiconductors and insulators makes it possible to design components and build electric circuits. Many circuits are powered with mains electricity, but portable electrical devices must use batteries of some kind. Electrical power fills the modern world with artificial light and sound, information and entertainment, remote sensing and control. The fundamentals of electromagnetism were worked out by scientists of the 19th century. However, power stations, like all machines, have a limited lifetime. If we all demand more electricity this means building new power stations in every generation – but what mix of power stations can promise a sustainable future?
Biology: Bioenergetics In this section we will explore how plants harness the Sun’s energy in photosynthesis in order to make food. This process liberates oxygen which has built up over millions of years in the Earth’s atmosphere. Both animals and plants use this oxygen to oxidise food in a process called aerobic respiration which transfers the energy that the organism needs to perform its functions. Conversely, anaerobic respiration does not require oxygen to transfer energy. During vigorous exercise the human body is unable to supply the cells with sufficient oxygen and it switches to anaerobic respiration. This process will supply energy but also causes the build-up of lactic acid in muscles which causes fatigue.
Chemistry:Quantitative chemistry
Chemists use quantitative analysis to determine the formulae of compounds and the equations for reactions. Given this information, analysts can then use quantitative methods to determine the purity of chemical samples and to monitor the yield from chemical reactions. Chemical reactions can be classified in various ways. Identifying different types of chemical reaction allows chemists to make sense of how different chemicals react together, to establish patterns and to make predictions about the behaviour of other chemicals. Chemical equations provide a means of representing chemical reactions and are a key way for chemists to communicate chemical ideas.
Physics: Particle model of matter
The particle model is widely used to predict the behaviour of solids, liquids and gases and this has many applications in everyday life. It helps us to explain a wide range of observations and engineers use these principles when designing vessels to withstand high pressures and temperatures, such as submarines and spacecraft. It also explains why it is difficult to make a good cup of tea high up a mountain!
Biology :Homeostasisand response Cells in the body can only survive within narrow physical and chemical limits. They require a constant temperature and pH as well as a constant supply of dissolved food and water. To do this the body requires control systems that constantly monitor and adjust the composition of the blood and tissues. These control systems include receptors which sense changes and effectors that bring about changes. In this section we will explore the structure and function of the nervous system and how it can bring about fast responses. We will also explore the hormonal system which usually brings about much slower changes. Hormonal coordination is particularly important in reproduction since it controls the menstrual cycle. An understanding of the role of hormones in reproduction has allowed scientists to develop not only contraceptive drugs but also drugs which can increase fertility.
Chemistry: Energy changes
Energy changes are an important part of chemical reactions. The interaction of particles often involves transfers of energy due to the breaking and formation of bonds. Reactions in which energy is released to the surroundings are exothermic reactions, while those that take in thermal energy are endothermic. These interactions between particles can produce heating or cooling effects that are used in a range of everyday applications. Some interactions between ions in an electrolyte result in the production of electricity. Cells and batteries use these chemical reactions to provide electricity. Electricity can also be used to decompose ionic substances and is a useful means of producing elements that are too expensive to extract any other way.
Physics: Atomic structure Ionising radiation is hazardous but can be very useful. Although radioactivity was discovered over a century ago, it took many nuclear physicists several decades to understand the structure of atoms, nuclear forces and stability. Early researchers suffered from their exposure to ionising radiation. Today radioactive materials are widely used in medicine, industry, agriculture and electrical power generation.
Biology :Homeostasis and response Cells in the body can only survive within narrow physical and chemical limits. They require a constant temperature and pH as well as a constant supply of dissolved food and water. To do this the body requires control systems that constantly monitor and adjust the composition of the blood and tissues. These control systems include receptors which sense changes and effectors that bring about changes. In this section we will explore the structure and function of the nervous system and how it can bring about fast responses. We will also explore the hormonal system which usually brings about much slower changes. Hormonal coordination is particularly important in reproduction since it controls the menstrual cycle. An understanding of the role of hormones in reproduction has allowed scientists to develop not only contraceptive drugs but also drugs which can increase fertility.
Chemistry: The rate and extent of chemical change
Chemical reactions can occur at vastly different rates. Whilst the reactivity of chemicals is a significant factor in how fast chemical reactions proceed, there are many variables that can be manipulated in order to speed them up or slow them down. Chemical reactions may also be reversible and therefore the effect of different variables needs to be established in order to identify how to maximise the yield of desired product. Understanding energy changes that accompany chemical reactions is important for this process. In industry, chemists and chemical engineers determine the effect of different variables on reaction rate and yield of product. Whilst there may be compromises to be made, they carry out optimisation processes to ensure that enough product is produced within a sufficient time, and in an energy-efficient way.
Physics: Forces
Engineers analyse forces when designing a great variety of machines and instruments, from road bridges and fairground rides to atomic force microscopes. Anything mechanical can be analysed in this way. Recent developments in artificial limbs use the analysis of forces to make movement possible.
Scalar and vector quantities, Contact and non-contact forces, Gravity, Resultant forces and Work done and energy transfer.
Biology: Inheritance In this section we will discover how the number of chromosomes are halved during meiosis and then combined with new genes from the sexual partner to produce unique offspring. Gene mutations occur continuously and on rare occasions can affect the functioning of the animal or plant. These mutations may be damaging and lead to a number of genetic disorders or death.
Chemistry: Organic chemistry
The chemistry of carbon compounds is so important that it forms a separate branch of chemistry. A great variety of carbon compounds is possible because carbon atoms can form chains and rings linked by C-C bonds. This branch of chemistry gets its name from the fact that the main sources of organic compounds are living, or once-living materials from plants and animals. These sources include fossil fuels which are a major source of feedstock for the petrochemical industry. Chemists are able to take organic molecules and modify them in many ways to make new and useful materials such as polymers, pharmaceuticals, perfumes and flavourings, dyes and detergents
Physics: Forces
Engineers analyse forces when designing a great variety of machines and instruments, from road bridges and fairground rides to atomic force microscopes. Anything mechanical can be analysed in this way. Recent developments in artificial limbs use the analysis of forces to make movement possible.
Scalar and vector quantities, Contact and non-contact forces, Gravity, Resultant forces and Work done and energy transfer.
Forces and motion, acceleration and Newton’s Laws of motion, Forces and braking and Momentum.
Biology: Variation & Evolution Gene mutations occur continuously and on rare occasions can affect the functioning of the animal or plant. These mutations may be damaging and lead to a number of genetic disorders or death. Very rarely a new mutation can be beneficial and consequently, lead to increased fitness in the individual. Variation generated by mutations and sexual reproduction is the basis for natural selection; this is how species evolve. An understanding of these processes has allowed scientists to intervene through selective breeding to produce livestock with favoured characteristics. Once new varieties of plants or animals have been produced it is possible to clone individuals to produce larger numbers of identical individuals all carrying the favourable characteristic. Scientists have now discovered how to take genes from one species and introduce them in to the genome of another by a process called genetic engineering. In spite of the huge potential benefits that this technology can offer, genetic modification still remains highly controversial.
Chemistry: Organic chemistry
The chemistry of carbon compounds is so important that it forms a separate branch of chemistry. A great variety of carbon compounds is possible because carbon atoms can form chains and rings linked by C-C bonds. This branch of chemistry gets its name from the fact that the main sources of organic compounds are living, or once-living materials from plants and animals. These sources include fossil fuels which are a major source of feedstock for the petrochemical industry. Chemists are able to take organic molecules and modify them in many ways to make new and useful materials such as polymers, pharmaceuticals, perfumes and flavourings, dyes and detergents
Physics: WavesWave behaviour is common in both natural and man-made systems. Waves carry energy from one place to another and can also carry information. Designing comfortable and safe structures such as bridges, houses and music performance halls requires an understanding of mechanical waves. Modern technologies such as imaging and communication systems show how we can make the most of electromagnetic waves.
We know that students who read well achieve well. As such all subject areas are committed to providing regular opportunities to read extensively. We provide regular opportunities for students to read for pleasure and to receive small group interventions if their reading skills are lower than we would expect.
Year 11 KS4 Curriculum
Our Key Stage 4 Curriculum
At Key Stage 4 students follow the AQA Exam board, taking either Separate Science or Combined Science: Trilogy.
KS 4 Half Term 1 Half Term 2 Half Term 3 Half Term 4 Half Term 5 Half Term 6 Year 11 Biology: Homeostasisand response Cells in the body can only survive within narrow physical and chemical limits. They require a constant temperature and pH as well as a constant supply of dissolved food and water. To do this the body requires control systems that constantly monitor and adjust the composition of the blood and tissues. These control systems include receptors which sense changes and effectors that bring about changes. In this section we will explore the structure and function of the nervous system and how it can bring about fast responses. We will also explore the hormonal system which usually brings about much slower changes. Hormonal coordination is particularly important in reproduction since it controls the menstrual cycle. An understanding of the role of hormones in reproduction has allowed scientists to develop not only contraceptive drugs but also drugs which can increase fertility.
Chemistry: The rate and extent of chemical change
Chemical reactions can occur at vastly different rates. Whilst the reactivity of chemicals is a significant factor in how fast chemical reactions proceed, there are many variables that can be manipulated in order to speed them up or slow them down. Chemical reactions may also be reversible and therefore the effect of different variables needs to be established in order to identify how to maximise the yield of desired product. Understanding energy changes that accompany chemical reactions is important for this process. In industry, chemists and chemical engineers determine the effect of different variables on reaction rate and yield of product. Whilst there may be compromises to be made, they carry out optimisation processes to ensure that enough product is produced within a sufficient time, and in an energy-efficient way.
Physics: Forces
Engineers analyse forces when designing a great variety of machines and instruments, from road bridges and fairground rides to atomic force microscopes. Anything mechanical can be analysed in this way. Recent developments in artificial limbs use the analysis of forces to make movement possible.
Biology: Inheritance, Variation and Evolution In this section we will discover how the number of chromosomes are halved during meiosis and then combined with new genes from the sexual partner to produce unique offspring. Gene mutations occur continuously and on rare occasions can affect the functioning of the animal or plant. These mutations may be damaging and lead to a number of genetic disorders or death. Very rarely a new mutation can be beneficial and consequently, lead to increased fitness in the individual. Variation generated by mutations and sexual reproduction is the basis for natural selection; this is how species evolve. An understanding of these processes has allowed scientists to intervene through selective breeding to produce livestock with favoured characteristics. Once new varieties of plants or animals have been produced it is possible to clone individuals to produce larger numbers of identical individuals all carrying the favourable characteristic. Scientists have now discovered how to take genes from one species and introduce them in to the genome of another by a process called genetic engineering. In spite of the huge potential benefits that this technology can offer, genetic modification still remains highly controversial.
Chemistry: Organic chemistry
The chemistry of carbon compounds is so important that it forms a separate branch of chemistry. A great variety of carbon compounds is possible because carbon atoms can form chains and rings linked by C-C bonds. This branch of chemistry gets its name from the fact that the main sources of organic compounds are living, or once-living materials from plants and animals. These sources include fossil fuels which are a major source of feedstock for the petrochemical industry. Chemists are able to take organic molecules and modify them in many ways to make new and useful materials such as polymers, pharmaceuticals, perfumes and flavourings, dyes and detergents.
Physics: WavesWave behaviour is common in both natural and man-made systems. Waves carry energy from one place to another and can also carry information. Designing comfortable and safe structures such as bridges, houses and music performance halls requires an understanding of mechanical waves. Modern technologies such as imaging and communication systems show how we can make the most of electromagnetic waves.
Biology: Ecology The Sun is a source of energy that passes through ecosystems. Materials including carbon and water are continually recycled by the living world, being released through respiration of animals, plants and decomposing microorganisms and taken up by plants in photosynthesis. All species live in ecosystems composed of complex communities of animals and plants dependent on each other and that are adapted to particular conditions, both abiotic and biotic. These ecosystems provide essential services that support human life and continued development. In order to continue to benefit from these services humans need to engage with the environment in a sustainable way. In this section we will explore how humans are threatening biodiversity as well as the natural systems that support it. We will also consider some actions we need to take to ensure our future health, prosperity and well-being.
Chemistry: Chemical analysis and Chemistry of the atmosphere
Analysts have developed a range of qualitative tests to detect specific chemicals. The tests are based on reactions that produce a gas with distinctive properties, or a colour change or an insoluble solid that appears as a precipitate. Instrumental methods provide fast, sensitive and accurate means of analysing chemicals, and are particularly useful when the amount of chemical being analysed is small. Forensic scientists and drug control scientists rely on such instrumental methods in their work. Chemistry of the atmosphere The Earth’s atmosphere is dynamic and forever changing. The causes of these changes are sometimes man-made and sometimes part of many natural cycles. Scientists use very complex software to predict weather and climate change as there are many variables that can influence this. The problems caused by increased levels of air pollutants require scientists and engineers to develop solutions that help to reduce the impact of human activity.
Physics: Magnetism and electromagnetismElectromagnetic effects are used in a wide variety of devices. Engineers make use of the fact that a magnet moving in a coil can produce electric current and also that when current flows around a magnet it can produce movement. It means that systems that involve control or communications can take full advantage of this.
Revision and Exam technique – Biology and Physics Chemistry: Using resources
Industries use the Earth’s natural resources to manufacture useful products. In order to operate sustainably, chemists seek to minimise the use of limited resources, use of energy, waste and environmental impact in the manufacture of these products. Chemists also aim to develop ways of disposing of products at the end of their useful life in ways that ensure that materials and stored energy are utilised. Pollution, disposal of waste products and changing land use has a significant effect on the environment, and environmental chemists study how human activity has affected the Earth’s natural cycles, and how damaging effects can be minimised.
Revision and Exam technique – Biology and Physics Exams We know that students who read well achieve well. As such all subject areas are committed to providing regular opportunities to read extensively. We provide regular opportunities for students to read for pleasure and to receive small group interventions if their reading skills are lower than we would expect.
KS5 Curriculum
Our Key Stage 5 Curriculum:
Click here to view the KS5 Chemistry curriculum intent for2022-2023.
Click here to view the KS5 Biology curriculum intent for 2022-2023.
Click here to view the KS5 Environmental Science curriculum intent for 2022-2023.
We know that students who read well achieve well. As such all subject areas are committed to providing regular opportunities to read extensively. We provide regular opportunities for students to read for pleasure and to receive small group interventions if their reading skills are lower than we would expect.
How does our Curriculum cater for students with SEND?
Sandhill View is an inclusive academy where every child is valued and respected. We are committed to the inclusion, progress and independence of all our students, including those with SEN. We work to support our students to make progress in their learning, their emotional and social development and their independence. We actively work to support the learning and needs of all members of our community.
A child or young person has SEN if they have a learning difficulty or disability which calls for special educational provision to be made that is additional to or different from that made generally for other children or young people of the same age. (CoP 2015, p16)
Teachers are responsible for the progress of ALL students in their class and high-quality teaching is carefully planned; this is the first step in supporting students who may have SEND. All students are challenged to do their very best and all students at the Academy are expected to make at least good progress.
Specific approaches which are used within the curriculum areas include:
- Seating plans to allow inclusion
- Use of differentiation in lessons including challenge and support, differentiated tasks and differentiated reading materials.
- Where possible, use of additional support from adults is planned and communicated in advance.
- Intervention strategies are used when required.
- Written and verbal feedback to stretch and support pupil progress.
- Ensure all resources are accessible to all pupils
- Homework tasks to promote literacy and independent study.
- Use of data to support planning
- Group work
- Questioning and class discussion
How does our curriculum cater for disadvantaged students and those from minority groups?
As a school serving an area with high levels of deprivation, we work tirelessly to raise the attainment for all students and to close any gaps that exist due to social contexts. The deliberate allocation of funding and resources has ensured that attainment gaps are closing in our drive to ensure that all pupils are equally successful when they leave the Academy. More specifically within the teaching of Science, we:
- Provide targeted support for underperforming pupils;
- Use data to identify gaps and underperforming pupils;
- Discuss strategies and implement these in order to address pupils needs;
- Provide knowledge organisers for all pupils to support with essential, core, substantive knowledge;
- Ensure homework is accessible and where needed resources and support are provided outside of lesson time;
Provide revision materials to pupils to reduce financial burdens on families.
How do we make sure that our curriculum is implemented effectively?
The Science curriculum leader is responsible for designing the Science curriculum and monitoring implementation.
The subject leader’s monitoring is validated by senior leaders.
Staff have regular access to professional development/training to ensure that curriculum requirements are met.
Effective assessment informs staff about areas in which interventions are required. These interventions are delivered during curriculum time to enhance pupils’ capacity to access the full curriculum.
Curriculum resources are selected carefully and reviewed regularly.
Assessments are designed thoughtfully to assess student progress and also to shape future learning.
Consistency, accuracy and reliability of assessments are validated through standardisation, which is then quality assured by the Science curriculum leader.
Members of the department mark for the AQA, OCR and Edexcel exam boards and provide CPD to the rest of the department to improve reliability of data.
Gap analysis is used following summative assessments to inform subsequent teaching, identify gaps in knowledge and plan more specific, targeted intervention if required.
How do we make sure our curriculum is having the desired impact?
- Examination results analysis and evaluation, reported to the senior leaders and the local governing body to ensure challenge
- Termly assessments-analysis and evaluation meetings
- Lesson observations
- Learning walks
- Book scrutiny
- Regular feedback from Teaching Staff during department meetings
- Regular feedback from Middle Leaders during curriculum meetings
- Pupil surveys
- Parental feedback
- External reviews and evaluations