Glossopdale School

Science

 

Curriculum Content: Science 2019-20

 

 

Aims and ambitions:

To show students that Science is exciting and relevant to their everyday lives so they can make informed decisions about topical subjects like global warming and vaccination programs.

To improve student’s core science knowledge by scaffolding their understanding, which will act as a springboard for deeper understanding.

To encourage students to be students curious of their surrounding and question how things work.

 

 

Year group

Topics include

By the end of the year, students should know:

 

7

Organisms

  • Skeleton
  • Muscles
  • Multicellular organisms

Ecosystems

  • Food webs 

Interdependence

  • Seed dispersal

Genes

  • Variation
  • Menstrual cycle

Matter

Solids liquids and gases

Mixtures can be separated

Reactions

  • Metals and non-metals
  • Acids and alkalis

Earth

  • Earth Structure.
  • Universe

Forces

  • Speed
  • gravity

Electromagnets

  • voltage and resistance
  • current

Energy

  • energy costs
  • energy transfers

Waves

  • sound
  • light

 

Assessment

Each paper will be assessed by multiple choice, structured, closed short answer and open responses.

 1st Matter and forces. Applications of science skills (Wk 10)

2nd Matter, forces, organisms, reactions, and electromagnets (wk 20)

3rd All year 7 modules (wk 35)

  • The parts of the human skeleton work as a system for support, protection, movement and the production of new blood cells. Antagonistic pairs of muscles create movement when one contracts and the other relaxes
  • Multicellular organisms are composed of cells which are organised into tissues, organs and systems to carry out life processes. There are many types of cell. Each has a different structure or feature so it can do a specific job.
  • Organisms in a food web (decomposers, producers and consumers) depend on each other for nutrients. So, a change in one population leads to changes in others. The population of a species is affected by the number of its predators and prey, disease, pollution and competition between individuals for limited resources such as water and nutrients.
  • Plants have adaptations to disperse seeds using wind, water or animals. Plants reproduce sexually to produce seeds, which are formed following fertilisation in the ovary.
  • There is variation between individuals of the same species. Some variation is inherited, some is caused by the environment and some is a combination. Variation between individuals is important for the survival of a species, helping it to avoid extinction in an always changing environment.
  • The menstrual cycle prepares the female for pregnancy and stops if the egg is fertilised by a sperm. The developing foetus relies on the mother to provide it with oxygen and nutrients, to remove waste and protect it against harmful substances.
  • Properties of solids, liquids and gases can be described in terms of particles in motion but with differences in the arrangement and movement of these same particles: closely spaced and vibrating (solid), in random motion but in contact (liquid), or in random motion and widely spaced (gas). Observations where substances change temperature or state can be described in terms of particles gaining or losing energy.
  • A pure substance consists of only one type of element or compound and has a fixed melting and boiling point. Mixtures may be separated due to differences in their physical properties. The method chosen to separate a mixture depends on which physical properties of the individual substances are different.  Metals and non-metals react with oxygen to form oxides which are either bases or acids. Metals can be arranged as a reactivity series in order of how readily they react with other substances. Some metals react with acids to produce salts and hydrogen.
  • The pH of a solution depends on the strength of the acid: strong acids have lower pH values than weak acids. Mixing an acid and alkali produces a chemical reaction, neutralisation, forming a chemical called a salt and water.  
  • Sedimentary, igneous and metamorphic rocks can be inter converted over millions of years through weathering and erosion, heat and pressure, and melting and cooling.
  • The solar system can be modelled as planets rotating on tilted axes while orbiting the Sun, moons orbiting planets and sunlight spreading out and being reflected. This explains day and year length, seasons and the visibility of objects from Earth. Our solar system is a tiny part of a galaxy, one of many billions in the Universe. Light takes minutes to reach Earth from the Sun, four years from our nearest star and billions of years from other galaxies.
  • If the overall, resultant force on an object is non-zero, its motion changes and it slows down, speeds up or changes direction.  
  • Mass and weight are different but related. Mass is a property of the object; weight depends upon mass but also on gravitational field strength. Every object exerts a gravitational force on every other object. The force increases with mass and decreases with distance. Gravity holds planets and moons in orbit around larger bodies.
  • We can model voltage as an electrical push from the battery, or the amount of energy per unit of charge transferred through the electrical pathway. In a series circuit, voltage is shared between each component. In a parallel circuit, voltage is the same across each loop. Components with resistance reduce the current flowing and shift energy to the surroundings.
  • Current is a movement of electrons and is the same everywhere in a series circuit. Current divides between loops in a parallel circuit, combines when loops meet, lights up bulbs and makes components work. Around a charged object, the electric field affects other charged objects, causing them to be attracted or repelled. The field strength decreases with distance.
  • We pay for our domestic electricity usage based on the amount of energy transferred. Electricity is generated by a combination of resources which each have advantages and disadvantages. Calculate the cost of home energy usage, using the formula: cost = power (kW ) x time (hours) x price (per kWh).
  • We can describe how jobs get done using an energy model where energy is transferred from one store at the start to another at the end. When energy is transferred, the total is conserved, but some energy is dissipated, reducing the useful energy.
  • Sound consists of vibrations which travel as a longitudinal wave through substances. The denser the medium, the faster sound travels. The greater the amplitude of the waveform, the louder the sound. The greater the frequency (and therefore the shorter the wavelength), the higher the pitch.  
  • When a light ray meets a different medium, some of it is absorbed and some reflected. For a mirror, the angle of incidence equals the angle of reflection. The ray model can describe the formation of an image in a mirror and how objects appear different colours. When light enters a denser medium it bends towards the normal; when it enters a less dense medium it bends away from the normal. Refraction through lenses and prisms can be described using a ray diagram as a model.

 

8

Helical revisiting year 7 topics and extending knowledge.

 

Organisms

  • Breathing
  • Digestion

Ecosystems

  • Respiration
  • Photosynthesis

Genes

  • Evolution
  • Inheritance

Matter

  • Periodic table
  • Elements

Reactions

  • Chemical energy
  • Types of transfers

Earth

  • Climate
  • Earth resources

Forces

  • Contact forces
  • Pressure

Electromagnets

  • Electromagnets
  • Magnetism

Energy

  • Heating and cooling

Waves

  • Wave effects
  • Wave properties

Assessment

Each paper will be assessed by multiple choice, structured, closed short answer and open response.

 

 1st All year 7 modules including light and sound (taught in year 8) and matter light organisms forces. (Wk 9)

 

2nd  All year 7 modules and matter light organisms forces and sound. Also reactions ecosystems and electromagnets (wk 23)

 

3rd All year 7 &8 modules (wk 36)

 

  • In gas exchange, oxygen and carbon dioxide move between alveoli and the blood. Oxygen is transported to cells for aerobic respiration and carbon dioxide, a waste product of respiration, is removed from the body. Breathing occurs through the action of muscles in the ribcage and diaphragm. The amount of oxygen required by body cells determines the rate of breathing
  • The body needs a balanced diet with carbohydrates, lipids, proteins, vitamins, minerals, dietary fibre and water, for its cells’ energy, growth and maintenance. Organs of the digestive system are adapted to break large food molecules into small ones which can travel in the blood to cells and are used for life processes.
  • Respiration is a series of chemical reactions, in cells, that breaks down glucose to provide energy and form new molecules. Most living things use aerobic respiration but switch to anaerobic respiration, which provides less energy, when oxygen is unavailable
  • Plants and algae do not eat, but use energy from light, together with carbon dioxide and water to make glucose (food) through photosynthesis. They either use the glucose as an energy source, to build new tissue, or store it for later use. Plants have specially-adapted organs that allow them to obtain resources needed for photosynthesis.
  • Natural selection is a theory that explains how species evolve and why extinction occurs. Biodiversity is vital to maintaining populations. Within a species variation helps against environment changes, avoiding extinction. Within an ecosystem, having many different species ensures resources are available for other populations, like humans.
  • Inherited characteristics are the result of genetic information, in the form of sections of DNA called genes, being transferred from parents to offspring during reproduction. Chromosomes are long pieces of DNA which contain many genes. Gametes, carrying half the total number of chromosomes of each parent, combine during fertilisation.
  • The elements in a group all react in a similar way and sometimes show a pattern in reactivity. As you go down a group and across a period the elements show patterns in physical properties. Most substances are not pure elements, but compounds or mixtures containing atoms of different elements. They have different properties to the elements they contain.
  • During a chemical reaction bonds are broken (requiring energy) and new bonds formed (releasing energy). If the energy released is greater than the energy required, the reaction is exothermic. If the reverse, it is endothermic.
  • Combustion is a reaction with oxygen in which energy is transferred to the surroundings as heat and light. Thermal decomposition is a reaction where a single reactant is broken down into simpler products by heating. Chemical changes can be described by a model where atoms and molecules in reactants rearrange to make the products and the total number of atoms is conserved.
  • Carbon is recycled through natural processes in the atmosphere, ecosystems, oceans and the Earth’s crust (such as photosynthesis and respiration) as well as human activities (burning fuels). Greenhouse gases reduce the amount of energy lost from the Earth through radiation and therefore the temperature has been rising as the concentration of those gases has risen.
  • Scientists have evidence that global warming caused by human activity is causing changes in climate.

There is only a certain quantity of any resource on Earth, so the faster it is extracted, the sooner it will run out.

  • Reduces the need to extract resources. Most metals are found combined with other elements, as a compound, in ores. The more reactive a metal, the more difficult it is to separate it from its compound. Carbon displaces less reactive metals, while electrolysis is needed for more reactive metals.
  • When the resultant force on an object is zero, it is in equilibrium and does not move, or remains at constant speed in a straight line. One effect of a force is to change an object’s form, causing it to be stretched or compressed. In some materials, the change is proportional to the force applied.
  • Pressure acts in a fluid in all directions. It increases with depth due to the increased weight of fluid, and results in an up thrust.  Objects sink or float depending on whether the weight of the object is bigger or smaller than the up thrust. Different stresses on a solid object can be used to explain observations where objects scratch, sink into or break surfaces.
  • An electromagnet uses the principle that a current through a wire causes a magnetic field. Its strength depends on the current, the core and the number of coils in the solenoid.
  • Magnetic materials, electromagnets and the Earth create magnetic fields which can be described by drawing field lines to show the strength and direction. The stronger the magnet, and the smaller the distance from it, the greater the force a magnetic object in the field experiences.
  • Work is done and energy transferred when a force moves an object. The bigger the force or distance, the greater the work. Machines make work easier by reducing the force needed. Levers and pulleys do this by increasing the distance moved, and wheels reduce friction.
  • When a wave travels through a substance, particles move to and fro. Energy is transferred in the direction of movement of the wave. Waves of higher amplitude or higher frequency transfer more energy.
  • A physical model of a transverse wave demonstrates it moves from place to place, while the material it travels through does not, and describes the properties of speed, wavelength and reflection.

 

 

 

9

Cells

  • Cell structure
  • Cell division
  • Stem cells
  • Transport in cells

Organisation

  • The human digestive system
  • The heart and CHD
  • Non-communicable diseases
  • Cancer
  • Plant tissues

Atomic Structure

  • Atoms elements and compounds
  • Development of the atom
  • RAM
  • Periodic table

Quantitative chemistry

  • Conservation of mass
  • RFM
  • Moles

Electricity

  • Current PD and resistance
  • Domestic uses and safety

Particle model

  • Density of materials
  • Internal energy
  • Particle model

 

Assessment

Each paper will be assessed by multiple choice, structured, closed short answer and open response.

 

 

1st cell biology and electricity also year 7&8 modules (Wk 8)

 

 

2nd  Cell biology and electricity and skills (wk 15)

 

 

3rd Cell biology  electricity atom structure quantitative chem organisation and skills (wk 27)

 

  • Cells are the basic unit of all forms of life. The structural differences between types of cells enables them to perform specific functions within the organism. These differences in cells are controlled by genes in the nucleus.
  • For an organism to grow, cells must divide by mitosis producing two new identical cells. If cells are isolated at an early stage of growth before they have become too specialised, they can retain their ability to grow into a range of different types of cells.
  • This phenomenon has led to the development of stem cell technology. This is a new branch of medicine that allows doctors to repair damaged organs by growing new tissue from stem cells.
  • To understand the human digestive system which provides the body with nutrients and the respiratory system that provides it with oxygen and removes carbon dioxide. In each case they provide dissolved materials that need to be moved quickly around the body in the blood by the circulatory system. Damage to any of these systems can be debilitating if not fatal.
  • Although there has been huge progress in surgical techniques, especially with regard to coronary heart disease, many interventions would not be necessary if individuals reduced their risks through improved diet and lifestyle.
  • The plant’s transport system is dependent on environmental conditions to ensure that leaf cells are provided with the water and carbon dioxide that they need for photosynthesis.
  • The periodic table provides chemists with a structured organisation of the known chemical elements from which they can make sense of their physical and chemical properties.
  • The historical development of the periodic table and models of atomic structure provide good examples of how scientific ideas and explanations develop over time as new evidence emerges.
  • The arrangement of elements in the modern periodic table can be explained in terms of atomic structure which provides evidence for the model of a nuclear atom with electrons in energy levels.
  • 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.
  • 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 continue to demand more electricity this means building new power stations in every generation –but what mix of power stations can promise a sustainable future?
  • 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!
  • How energy stores can be transferred to chemical stores to raise their temperatures (specific heat capacity) or break their bonds (latent heat).

 

10

Infection and Response

  • Communicable diseases
  • Human defence system
  • Vaccination
  • Antibiotics
  • Drugs

Bioenergetics

  • Photosynthesis
  • Respiration
  • Exercise
  • Metabolism

Homeostasis

  • Control of human body
  • Nervous system
  • Endocrine system
  • Contraception
  • Negative feedback

Rates of reaction

  • Calculating rates
  • Reversible reactions

Chemistry of the Atmosphere

  • Composition of Earth atmosphere
  • Greenhouse gases
  • Pollutants

Using Resources

  • Potable water
  • LCA

Energy

  • Energy stores
  • Power
  • Conservation of energy

Forces

  • Forces and their interactions
  • Motion
  • Newtons Laws
  • Momentum

Atomic Structure (physics)

  • Atoms and isotopes
  • Nuclear radiation

Waves

  • Waves in air fluids and solids
  • Electromagnets

Assessment

Each paper will be assessed by multiple choice, structured, closed short answer and open response

 

 

1st cells, waves, organisation, bonding, atom structure, quantitative chemistry, energy electricity and infection (Wk 11)

 

 

2nd  Paper 1 2018 (wk 22)

 

 

3rd Paper 2 2019 (wk 29-30)

 

  • 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.
  • Explore how we can avoid diseases by reducing contact with them, as well as how the body uses barriers against pathogens.
  • Once inside the body our immune system is triggered which is usually strong enough to destroy the pathogen and prevent disease. When at risk from unusual or dangerous diseases our body's natural system can be enhanced by the use of vaccination.
  • Since the 1940s a range of antibiotics have been developed which have proved successful against a number of lethal diseases caused by bacteria. Unfortunately many groups of bacteria have now become resistant to these antibiotics. The race is now on to develop a new set of antibiotics.
  • 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.
  • 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. In order 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.
  • Explore the structure and function of the nervous system and how it can bring about fast responses. 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.
  • 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.
  • 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.
  • 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.
  • Energy cannot be created or destroyed it can only be transferred from one store to another.
  • Stored gravitational energy can be used in theme park rides to produce kinetic energy. Other energy stores are produced that are less useful so this energy is said to be dissipated.
  • Energy stores are used to do work.  The efficiency of these transfers can be increased.
  • It is very important that national and global energy stores are maintained at a sustainable level.
  • The interactions of forces allows us to explain gravity and resultant forces.
  • Scientist 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.
  • Understanding motion and using graphs to interpret data. Using Newton’s Laws of motion to explain how materials react.
  • 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. Rules for radiological protection were first introduced in the 1930s and subsequently improved. Today radioactive materials are widely used in medicine, industry, agriculture and electrical power generation.
  • Wave 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.

 

 

 

11

Inheritance and Evolution

  • Sexual and asexual reproduction
  • Meiosis
  • DNA and genome
  • Variation
  • Evolution
  • Selective breeding
  • Genetic engineering
  • Extinction
  • Classification

Ecology

  • Communities
  • Adaptations
  • Levels of organisation
  • Cycles
  • Biodiversity
  • Waste control
  • Land use
  • Deforestation
  • Global warming

Chemical change

  • Reactivity of metals
  • Reaction of acids
  • Electrolysis

Energy change

  • Exothermic reactions
  • Reaction profiles
  • Fuel cells

Organic Chemistry

  • Carbon compounds
  • Polymers

Chemical analysis

  • Purity of chemicals
  • Identification of gases

Magnetism

  • Permanent magnets
  • Motor effect

Space (phy)

 

 

Each paper will be assessed by multiple choice, structured, closed short answer and open response

 

 

1st Specimen paper 1 trilogy (Wk 7)

 

 

2nd  Paper 1 2019 (wk 13-14)

 

 

3rd Paper 2 2019 (wk 24)

  • 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.
  • 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.
  • Explore how humans are threatening biodiversity as well as the natural systems that support it. Consider some actions we need to take to ensure our future health, prosperity and well-being.
  • Understanding of chemical changes began 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’.
  • Scientist can predict how acids react with metals bases and carbonates. Using this to produce useful salts often for fertilisers.
  • 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.
  • 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.
  • Organic 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.
  • 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.
  • Electromagnetic 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.
  • In the past century, astronomers and astrophysicists have made remarkable progress in understanding the scale and structure of the universe, its evolution and ours. New questions have emerged recently. ‘Dark matter’, which bends light and holds galaxies together but does not emit electromagnetic radiation, is everywhere – what is it? And what is causing the universe to expand ever faster?

 

 

 

GCSE Key Information

Reactions

Qualification

GCSE trilogy AQA double award or GCSE AQA separate sciences

 

Exam board

AQA

 

Website link

https://www.aqa.org.uk/subjects/science/gcse/biology-8461

https://www.aqa.org.uk/subjects/science/gcse/chemistry-8462

https://www.aqa.org.uk/subjects/science/gcse/physics-8463

https://www.aqa.org.uk/subjects/science/gcse/combined-science-trilogy-8464

 

Exam structure and content

  • Separate sciences have two written exam for 1 hour 45 minutes for each subject. (100 marks.
  • The papers are at Foundation and Higher Tier
  • Trilogy Science have six written exam for 1 hour 15 minutes (70 marks)
  • The papers are at Foundation and Higher Tier
  • Each paper will be assessed by multiple choice, structured, closed short answer and open response.

Chemistry

  • Topics 1–5: Atomic structure and the periodic table; Bonding, structure, and the properties of matter; Quantitative chemistry, Chemical changes; and Energy changes.
  • Topics 6–10: The rate and extent of chemical change; Organic chemistry; Chemical analysis, Chemistry of the atmosphere; and using resources.

Biology

  • Topics 1–4: Cell biology; Organisation; Infection and response; and Bioenergetics.
  • Topics 5–7: Homeostasis and response; Inheritance, variation and evolution; and Ecology.

Physics

  • Topics 1-4: Energy; Electricity; Particle model of matter; and Atomic structure.
  • Topics 5-8: Forces; Waves; Magnetism and electromagnetism; and Space physics.

 

Recommended revision guide

CPG Trilogy £5:50

CGP Separate science 3 x £2:75

 

Extra-curricular opportunities in

 

STEM

Salters Science ( Manchester University)

Science club

 

 

 

 

Big ideas

 

Year 7

Year 8

Year 9

Year 10

Year 11

Forces

 

 

Speed and gravity

Contact forces

pressure

 

Forces 1

Forces 2

Space

Electromagnets

Voltage and resistance

Current

 

Electromagnets

magnetism

Electricity part 1

Electricity part 2

 

Magnetism

Energy

Energy cost

Energy transfers

 

Work

Heating and cooling

Particle model

Energy.

Atomic Structure

Energy change

Waves

 

 

Sound and light

Wave effect

Wave properties

 

Waves

 

Matter

 

 

Particle model

separating

Periodic table

elements

Atomic structure (chem)

Quantitative chemistry

Particle model

Atom structure (phy)

 

Reactions

Metals and non-metals

Acids and alkalis

Chemical energy

Types of reactions

Bonding

Rates of reactions

 

Chemical change

Energy change

Organic chemistry

Chemical analysis

Earth

 

 

Earth structure

Universe

Climate

Earth resources

 

Chemistry of the Atmosphere.

Using Resources

Ecology

Organisms

 

 

Movement

Cells

Breathing

Digestion

B1 Cells

B2 Organisation

Infection and response

Homeostasis

 

Ecosystems

Interdependence

Plant reproduction

 

Respiration and photosynthesis

 

Bioenergetics

Ecology

genes

Variation

Human Reproduction

Evolution

Inheritance

 

 

 

Inheritance and evolution