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Victorian Curriculum and Assessment Authority

Science

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  1. 9-10

Levels 9 and 10

Levels 9 and 10 Description

In Levels 9 and 10, the curriculum focus is on explaining phenomena involving science and its applications. Students consider both classic and contemporary science contexts to explain the operation of systems at a range of scales. At a microscopic scale, they consider the atom as a system of protons, electrons and neutrons, and understand how this system can change through nuclear decay. They...

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Levels 9 and 10 Content Descriptions

Science Understanding

Science as a human endeavour Elaborations
  1. Scientific understanding, including models and theories, are contestable and are refined over time through a process of review by the scientific community (VCSSU114)
    1. considering how ideas about disease transmission have changed from medieval time to the present as knowledge has developed
    2. investigating the historical development of models of the structure of the atom
    3. investigating how the theory of plate tectonics developed, based on evidence from seafloor spreading and occurrence of earthquakes and volcanic activity
    4. recognising the contribution of Australian scientists, for example, Brian Schmidt and Penny Sackett, in the exploration and study of the Universe
  2. Advances in scientific understanding often rely on developments in technology and technological advances are often linked to scientific discoveries (VCSSU115)
    1. considering how the properties of electromagnetic radiation relate to its uses, for example, radar, medical diagnosis and treatment, mobile phone communications and microwave cooking
    2. considering how information technology can be applied to different areas of science, for example, bioinformatics, the Square Kilometre Array, DNA sequencing and the analysis of radio astronomy signals
    3. considering how computer modelling and imaging technologies has improved knowledge and predictability of phenomena, for example, climate change, atmospheric pollution, plate tectonic movement, and body system functions and interactions
  3. The values and needs of contemporary society can influence the focus of scientific research (VCSSU116)
    1. investigating how social actions have led to changed government policies and social behavioural change in relation to the use of chlorofluorocarbons (CFCs) in aerosol spray cans
    2. considering how choices related to the use of fuels are influenced by environmental, social and political considerations
    3. considering the use of genetic testing for decisions such as genetic counselling, embryo selection, identification of carriers of genetic mutations and the use of this information for personal use or by organisation such as insurance companies or medical facilities
Biological sciences Elaborations
  1. Multicellular organisms rely on coordinated and interdependent internal systems to respond to changes to their environment (VCSSU117)
    1. describing how the requirements for life (oxygen, nutrients, water and removal of waste) are provided through the coordinated function of body systems, for example, the respiratory, circulatory, digestive, nervous and excretory systems
    2. explaining (using models, flow diagrams or simulations) how body systems work together to maintain a functioning body
    3. investigating the response of the body to changes as a result of the presence of micro-organisms
  2. An animal’s response to a stimulus is coordinated by its central nervous system (brain and spinal cord); neurons transmit electrical impulses and are connected by synapses (VCSSU118)
    1. identifying functions for different areas of the brain
    2. modelling the 'knee jerk' reaction and explaining why it is a reflex action
    3. identifying responses involving the nervous and endocrine systems
    4. researching the causes and effects of spinal cord damage
  3. The transmission of heritable characteristics from one generation to the next involves DNA and genes (VCSSU119)
    1. using models and diagrams to represent the relationship between DNA, genes and chromosomes
    2. describing mutations as changes in DNA or chromosomes and outlining the factors that contribute to causing mutations
    3. recognising that genetic information passed on to offspring is from both parents and involves the processes of fertilisation and meiosis
    4. representing patterns of inheritance of a simple dominant/recessive characteristic through generations of a family
  4. The theory of evolution by natural selection explains the diversity of living things and is supported by a range of scientific evidence (VCSSU120)
    1. describing biodiversity as a function of evolution
    2. outlining processes involved in natural selection including variation, isolation and selection
    3. investigating changes caused by natural selection in a particular population as a result of a specified selection pressure, for example, artificial selection in breeding for desired characteristics
    4. evaluating and interpreting evidence for evolution, including the fossil record, chemical and anatomical similarities, and the geographical distribution of species
  5. Ecosystems consist of communities of interdependent organisms and abiotic components of the environment; matter and energy flow through these systems (VCSSU121)
    1. exploring interactions between organisms, for example, predator/prey, parasites, competitors, pollinators and disease vectors
    2. using modelling to examine factors that affect population sizes, for example, seasonal changes, destruction of habitats, introduced species
    3. investigating how ecosystems change as a result of environmental change, for example, bushfires, drought and flooding
Chemical sciences Elaborations
  1. All matter is made of atoms which are composed of protons, neutrons and electrons; natural radioactivity arises from the decay of nuclei in atoms (VCSSU122)
    1. describing and modelling the structure of atoms in terms of the nucleus, protons, neutrons and electrons
    2. comparing the mass and charge of protons, neutrons and electrons
    3. describing in simple terms how alpha and beta particles and gamma radiation are released from unstable atoms
  2. The atomic structure and properties of elements are used to organise them in the periodic table (VCSSU123)
    1. describing the structure of atoms in terms of electron shells
    2. explaining how the electronic structure of an atom determines its position in the periodic table and its properties
    3. investigating the chemical activity of metals
  3. Chemical reactions involve rearranging atoms to form new substances; during a chemical reaction mass is not created or destroyed (VCSSU124)
    1. modelling chemical reactions in terms of rearrangement of atoms
    2. considering the role of energy in chemical reactions
    3. recognising that the conservation of mass in a chemical reaction can be demonstrated by simple chemical equations
  4. Different types of chemical reactions are used to produce a range of products and can occur at different rates; chemical reactions may be represented by balanced chemical equations (VCSSU125)
    1. investigating how chemical reactions result in the production of a range of useful substances, for example, fuels, metals and pharmaceuticals
    2. using word or symbol equations to represent chemical reactions
    3. investigating the effect of a range of factors, for example, temperature and catalysts, on the rate of chemical reactions
  5. Chemical reactions, including combustion and the reactions of acids, are important in both non-living and living systems and involve energy transfer (VCSSU126)
    1. investigating a range of different reactions to classify them as exothermic or endothermic
    2. comparing respiration and photosynthesis and their role in biological processes
    3. investigating reactions of acids with metals, bases, and carbonates
Earth and space sciences Elaborations
  1. The theory of plate tectonics explains global patterns of geological activity and continental movement (VCSSU127)
    1. recognising the major plates on a world map
    2. considering the role of heat energy and convection currents in the movement of tectonic plates
    3. modelling sea-floor spreading
    4. relating the occurrence of earthquakes and volcanic activity to constructive and destructive plate boundaries
    5. relating the extreme age and stability of a large part of the Australian continent to its plate tectonic history
  2. Global systems, including the carbon cycle, rely on interactions involving the atmosphere, biosphere, hydrosphere and lithosphere (VCSSU128)
    1. modelling a nutrient cycle within the biosphere, for example, the carbon, nitrogen or phosphorus cycle
    2. investigating how human activity affects global systems
    3. distinguishing between 'natural' and 'enhanced' greenhouse effects
    4. investigating the effect of climate change on sea levels and biodiversity
  3. The Universe contains features including galaxies, stars and solar systems; the Big Bang theory can be used to explain the origin of the Universe (VCSSU129)
    1. identifying the evidence supporting the Big Bang theory, for example, Edwin Hubble’s observations and the detection of microwave radiation
    2. recognising that the age of the Universe can be derived by applying knowledge of the Big Bang theory
    3. describing how the evolution of the Universe, including the formation of galaxies and stars, has continued since the Big Bang
Physical sciences Elaborations
  1. Electric circuits can be designed for diverse purposes using different components; the operation of circuits can be explained by the concepts of voltage and current (VCSSU130)
    1. investigating parallel and series circuits and measuring voltage drops across and currents through various components
    2. investigating the properties of components such as LEDs, and temperature and light sensors
    3. comparing circuit design to household wiring
    4. exploring the use of sensors in robotics and control devices
  2. The interaction of magnets can be explained by a field model; magnets are used in the generation of electricity and the operation of motors (VCSSU131)
    1. investigating the action at a distance or the field model around magnets of different shapes
    2. investigating the movement of a magnet and a wire to produce electricity
    3. investigating the effect of a magnet on a current from a battery to produce movement
  3. Energy flow in Earth’s atmosphere can be explained by the processes of heat transfer (VCSSU132)
    1. recognising that the Law of Conservation of Energy explains that total energy is maintained in energy transfers and transformations
    2. recognising that in energy transfers and transformations, a number of steps can occur and the system is not 100% efficient so that usable energy is reduced
    3. comparing energy changes in physical events, for example, car crashes, the motion of pendulums, lifting and dropping
  4. The description and explanation of the motion of objects involves the interaction of forces and the exchange of energy and can be described and predicted using the laws of physics (VCSSU133)
    1. recognising that a stationary object, or a moving object with constant motion, has balanced forces acting on it
    2. gathering data to analyse everyday motion produced by forces, for example, measurements of distance and time, velocity, mass, acceleration and force
    3. investigating the effects of applying different forces, including Earth's gravitational force, to familiar objects

Science Inquiry Skills

Questioning and predicting Elaborations
  1. Formulate questions or hypotheses that can be investigated scientifically, including identification of independent, dependent and controlled variables (VCSIS134)
    1. formulating questions that can be investigated within the scope of the classroom or field with available resources
    2. developing ideas from students' own or others' investigations and experiences to investigate further
    3. revising and refining research questions to target specific information and data collection or finding a solution to the specific problem identified
Planning and conducting Elaborations
  1. Independently plan, select and use appropriate investigation types, including fieldwork and laboratory experimentation, to collect reliable data, assess risk and address ethical issues associated with these investigation types (VCSIS135)
    1. explaining the choice of variables to be controlled, changed and measured in an investigation
    2. identifying and managing potential hazards of chemicals or biological materials used in experimental investigations or fieldwork
    3. deciding how much data are needed to obtain reliable measurements
    4. using modelling and simulations, including using digital technologies, to investigate situations and events
    5. using the internet to facilitate collaboration in joint projects and discussions
  2. Select and use appropriate equipment and technologies to systematically collect and record accurate and reliable data, and use repeat trials to improve accuracy, precision and reliability (VCSIS136)
    1. applying specific skills in the use of scientific instruments
    2. selecting and using probes and data loggers to record information
    3. identifying how human error can influence the reliability of data
Recording and processing Elaborations
  1. Construct and use a range of representations, including graphs, keys, models and formulas, to record and summarise data from students’ own investigations and secondary sources, to represent qualitative and quantitative patterns or relationships, and distinguish between discrete and continuous data (VCSIS137)
    1. using spreadsheets to present data in tables and graphical forms and to carry out mathematical analyses of data
    2. designing and constructing appropriate graphs to represent data and to look for trends and patterns
Analysing and evaluating Elaborations
  1. Analyse patterns and trends in data, including describing relationships between variables, identifying inconsistencies in data and sources of uncertainty, and drawing conclusions that are consistent with evidence (VCSIS138)
    1. exploring relationships between variables using spreadsheets, databases, tables, charts, graphs and statistics
    2. describing data properties (for example mean, median, range, outliers, large gaps visible on a graph) and their significance for a particular investigation sample, acknowledging uncertainties
  2. Use knowledge of scientific concepts to evaluate investigation conclusions, including assessing the approaches used to solve problems, critically analysing the validity of information obtained from primary and secondary sources, suggesting possible alternative explanations and describing specific ways to improve the quality of data (VCSIS139)
    1. discussing what is meant by 'validity' and how we can evaluate the validity of information in secondary sources
    2. judging the validity of science-related media reports and how these reports might be interpreted by the public
    3. using primary or secondary scientific evidence to support or refute a conclusion or claim
    4. suggesting more than one possible explanation of the data presented
Communicating Elaborations
  1. Communicate scientific ideas and information for a particular purpose, including constructing evidence-based arguments and using appropriate scientific language, conventions and representations (VCSIS140)
    1. using secondary sources as well as students’ own findings to help explain a scientific concept
    2. using a range of representations, including mathematical and symbolic forms, to communicate science ideas
    3. presenting results and ideas using formal experimental reports, oral presentations, multimodal presentations, poster presentations and contributing to group discussions

Levels 9 and 10 Achievement Standard

By the end of Level 10, students analyse how models and theories have developed over time and discuss the factors that prompted their review. They predict how future applications of science and technology may affect people’s lives. They explain the concept of energy conservation and model energy transfer and transformation within systems. They analyse how biological systems function and respond to external changes with reference to the interdependencies between individual components, energy transfers and flows of matter. They evaluate the evidence for scientific theories that explain the origin of the Universe and the diversity of life on Earth. They explain the role of DNA and genes in cell division and genetic inheritance. They apply geological timescales to elaborate their explanations of both natural selection and evolution. They explain how similarities in the chemical behaviour of elements and their compounds and their atomic structures are represented in the way the periodic table has been constructed. They compare the properties of a range of elements representative of the major groups and periods in the periodic table. They use atomic symbols and balanced chemical equations...

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