Biology
Prerequisites
Students DO NOT need to study Units 1 and 2 before completing Units 3 and 4.
Course Description
Unit 1
Area of Study 1: How do cells function?
In this area of study students examine the structure and functioning of prokaryotic and eukaryotic cells, and how the plasma membrane contributes to survival by controlling the movement of substances into and out of the cell. Students explore cellular growth, replacement and death. They become familiar with the key events and regulation of the cell cycle and the processes for cell division, including disruptions to the cell cycle and deviant cell behaviour. Students consider the properties of stem cells and their role in differentiation, specialisation and renewal of cells and tissues.
Area of Study 2: How do plant and animal systems function?
In this area of study students explore how systems function through cell specialisation in vascular plants and in digestive, endocrine and excretory systems in animals, focusing on regulation of water balance in plants, and temperature, blood glucose and water balance in animals. Students examine how homeostatic mechanisms in animals help maintain their internal environment within a narrow range of tolerance levels, and consider malfunctions in homeostatic mechanisms.
Area of Study 3: How do scientific investigations develop understanding of how organisms regulate their functions?
Survival of organisms requires control and regulation of factors within an organism and often outside an organism. Different types of cells and adaptations enhance an organism’s survival
in a particular environment, while homeostatic mechanisms maintain the internal environment.
In this area of study students adapt or design and then conduct a scientific investigation to generate appropriate qualitative and/or quantitative data, organise and interpret the data, and reach a conclusion in response to the research question.
Unit 2
Area of Study 1: How is inheritance explained?
In this area of study students describe the production of gametes in sexual reproduction through the key events in meiosis. They explore the nature of chromosomes and the use of genetic language to read and interpret patterns of inheritance and predict outcomes of genetic crosses.
Students explain how a characteristic or trait can be influenced by one gene, many genes acting together, and genes interacting with external environmental or epigenetic factors. They apply their genetic knowledge to analyse pedigree charts, determine patterns of inheritance and predict outcomes of genetic crosses.
Area of Study 2: How do inherited adaptations impact on diversity?
In this area of study students analyse the advantages and disadvantages of asexual and sexual reproduction and investigate the use and application of reproductive cloning technologies. Students explore the biological importance of genetic diversity and the structural, physiological and behavioural adaptations that enable species to survive in an ecosystem.
Students explore the interdependencies between species, including the importance and impact of keystone species and top predators. They consider the contributions of Aboriginal and Torres Strait Islander knowledge and perspectives to the understanding of the adaptations of, and interdependencies between, species in Australian ecosystems.
Area of Study 3: How do humans use science to explore and communicate contemporary bioethical issues?
In this area of study students explore a contemporary bioethical issue relating to the application of genetic knowledge, reproductive science, inheritance or adaptations and interdependencies beneficial for survival.
Unit 3
Area of Study 1: What is the role of nucleic acids and proteins in maintaining life?
In this area of study students explore the expression of the information encoded in a sequence of DNA to form a protein and outline the nature of the genetic code and the proteome. They apply their knowledge to the structure and function of the DNA molecule to examine how molecular tools and techniques can be used to manipulate the molecule for a particular purpose. Students compare gene technologies used to address human and agricultural issues and consider the ethical implications of their use.
Area of Study 2: How are biochemical pathways regulated?
In this area of study students focus on the structure and regulation of biochemical pathways. They examine how biochemical pathways, specifically photosynthesis and cellular respiration, involve many steps that are controlled by enzymes and assisted by coenzymes. Students investigate factors that affect the rate of cellular reactions and explore applications of biotechnology that focus on the regulation of biochemical pathways.
Unit 4
Area of Study 1: How do organisms respond to pathogens?
In this area of study students focus on the immune response of organisms to specific pathogens. Students examine unique molecules called antigens and how they illicit an immune response, the nature of immunity and the role of vaccinations in providing immunity. They explain how technological advances assist in managing immune system disorders and how immunotherapies can be applied to the treatment of other diseases.
Students consider that in a globally connected world there are biological challenges that can be mediated by identification of pathogens, the prevention of spread and the development of treatments for diseases.
Area of Study 2: How are species related over time?
In this area of study students focus on changes to genetic material over time and the evidence for biological evolution. They consider how the field of evolutionary biology is based upon the accumulation of evidence over time and develop an understanding of how interpretations of evidence can change in the light of new evidence as a result of technological advances, particularly in molecular biology. Students consider the biological consequences of changes in allele frequencies and how isolation and divergence are required elements for speciation. They consider the evidence for determining the relatedness between species and examine the evidence for major trends in hominin evolution, including the migration of modern human populations around the world.
Area of Study 3: How is scientific inquiry used to investigate cellular processes and/or biological change?
Students undertake a student-designed scientific investigation in either Unit 3 or Unit 4, or across both Units 3 and 4. The investigation involves the generation of primary data relating to cellular processes and/or how life changes and responds to challenges. The investigation draws on knowledge and related key science skills developed across Units 3 and 4 and is undertaken by students in the laboratory and/or in the field.
Assessment is comprised of coursework (class tests and practical work), practical investigation and examination.
Chemistry
Prerequisites
Chemistry Units 1 & 2 must be completed before Units 3 & 4.
Course Description
Unit 1
Semester 1 – How can the diversity of materials be explained?
Area of Study 1: How do the chemical structures of materials explain their properties and reactions?
Students focus on elements as the building blocks of useful materials. They investigate the structures, properties and reactions of carbon compounds, metals and ionic compounds, and use chromatography to separate the components of mixtures. They use metal recycling as a context to explore the transition in manufacturing processes from a linear economy to a circular economy.
Area of Study 2: How are materials quantified and classified?
Students focus on the measurement of quantities in chemistry and the structures and properties of organic compounds, including polymers. They perform calculations based on the generation of primary data, such as determining the empirical formula of an ionic compound or hydrated salt, and consider how the quality of data generated in experiments can be improved. They may construct models to visualise the similarities and differences between families of organic compounds.
Area of Study 3: How can chemical principles be applied to create a more sustainable future?
Students undertake an investigation involving the selection and evaluation of a recent discovery, innovation, advance, case study, issue or challenge linked to the knowledge and skills developed in Unit 1 Area of Study 1 and/or Area of Study 2, including consideration of sustainability concepts (green chemistry principles, sustainable development and the transition towards a circular economy).
Unit 2
Semester 2: How do chemical reactions shape the natural world?
Area of Study 1: How do chemicals interact with water?
students focus on understanding the properties of water and investigating acid-base and redox reactions. They explore water’s properties, including its density, specific heat capacity and latent heat of vaporisation. They write equations for acid-base and redox reactions, and apply concepts including pH as a measure of acidity. They explore applications of acid-base reactions and redox reactions in society.
Area of Study 2: How are chemicals measured and analysed?
Students focus on the analysis and quantification of chemical reactions involving acids, bases, salts and gases. They measure the solubility of substances in water, explore the relationship between solubility and temperature using solubility curves, and learn to predict when a solute will dissolve or crystallise out of solution. They quantify amounts in chemistry using volumetric analysis, application of the ideal gas equation, stoichiometry and calibration curves.
Area of Study 3: How do quantitative scientific investigations develop our understanding of chemical reactions?
Students adapt or design and then conduct a scientific investigation related to chemical equations and/or analysis, which must include the generation of primary data. They develop a research question related to the production of gases, acid-base or redox reactions or the analysis of substances in water, and adapt or design and then conduct a scientific investigation to generate appropriate quantitative data. Students organise and interpret the data and reach a conclusion in response to their research question.
Unit 3
How can design and innovation help to optimise chemical processes?
The global demand for energy and materials is increasing with world population growth. In this unit students investigate the chemical production of energy and materials. They explore how innovation, design and sustainability principles and concepts can be applied to produce energy and materials while minimising possible harmful effects of production on human health and the environment.
Area of Study 1: What are the current and future options for supplying energy?
Students focus on analysing and comparing a range of fossil fuels and biofuels as energy sources for society, and carbohydrates, proteins and lipids as fuel sources for the body. They write balanced thermochemical equations for the combustion of various fuels. The amounts of energy and gases produced in combustion reactions are quantified using stoichiometry. They explore how energy can be sustainably produced from chemicals to meet the needs of society while minimising negative impacts on the environment. Students develop practical techniques to investigate how energy from fuels can be obtained and measured, and to determine the efficiency of different fuels and electrochemical cells as sources of energy. Students develop their skills in the use of scientific equipment and apparatus.
Area of Study 2: How can the rate and yield of chemical reactions be optimised?
Students explore the factors that affect the rate and yield of equilibrium and electrolytic reactions involved in producing important materials for society. Reactants and products in chemical reactions are treated qualitatively through the application of Le Chatelier’s principle and quantified using equilibrium expressions, reaction quotients and Faraday’s Laws. Students explore the sustainability of different options for producing useful materials for society. Students investigate reaction rates including the measurement of mass, gas volumes and time. They use an equilibrium system, such as iron(III) thiocyanate, to predict and test the effect of different changes to the system. They investigate the effect of catalysts on reaction rates, such as comparing the rate of decomposition of hydrogen peroxide using organic and inorganic catalysts. Students explore the application of electrolysis in the manufacture of useful products through experiments such as electroplating and anodising. They model and explain the operation of secondary cells: for example, those in portable devices such as laptops or cell phones.
Unit 4
How are carbon-based compounds designed for purpose?
In this unit students investigate the structures and reactions of carbon-based organic compounds, including considering how green chemistry principles are applied in the production of synthetic organic compounds. They study the metabolism of food and the action of medicines in the body. They explore how laboratory analysis and various instrumentation techniques can be applied to analyse organic compounds in order to identify them and to ensure product purity.
Students conduct practical investigations related to the synthesis and analysis of organic compounds, involving reaction pathways, organic synthesis, identification of functional groups, direct redox titrations, solvent extraction and distillations.
Area of Study 1: How are organic compounds categorised and synthesised?
Students focus on the structure, naming, properties and reactions of organic compounds, including the chemical reactions associated with the metabolism of food. They explore how synthetic organic compounds can be produced more sustainably for use in society.
Area of Study 2: How are organic compounds analysed and used?
Students focus on laboratory and instrumental analyses of organic compounds, and the function of some organic compounds as medicines. They use distillation to separate mixtures, use volumetric analysis to calculate redox quantities, and explore how instrumental analysis is used to ensure the quality of consumer products. Students explain how some medicines that bind to the active sites of enzymes function by inhibiting the enzymes’ mode of action.
Students may perform qualitative tests to identify features of organic compounds, such as the degree of saturation in fats and oils and the identification of functional groups in an unknown compound. Students may perform quantitative analyses including redox titrations to determine concentrations and quantities of substances, such as the amount of Vitamin C in fruits. They design and improve on experiments such as the testing of the viscosity of alcohols.
Area of Study 3: How is scientific inquiry used to investigate the sustainable production of energy and/or materials?
Students undertake a student-designed scientific investigation in either Unit 3 or Unit 4, or across both
Units 3 and 4. The investigation involves the generation of primary data related to the production of energy and/or chemicals and/or the analysis or synthesis of organic compounds, and should be inspired by a contemporary chemical challenge or issue. The investigation draws on knowledge and related key science skills developed across Units 3 and 4 and is undertaken by students in the laboratory and/or in the field.
Environmental Science
Prerequisites:
There are no prerequisites for this course.
Course Description:
Environmental Science Units 1/2
Environmental Science is an exciting and relevant subject that explores the complex interactions between humans and the natural world. Through Units 1 and 2, students will develop an understanding of key environmental concepts, including ecosystems, biodiversity, and sustainability, and investigate the impacts of human activities on the environment.
In Unit 1, students will explore the biotic and abiotic components of ecosystems, including energy flow and nutrient cycles, and investigate the importance of biodiversity and the role of conservation in maintaining ecosystem health. They will also examine the impact of human activities, such as land use change and pollution, on ecosystems.
In Unit 2, students will deepen their understanding of environmental issues, investigating the factors that contribute to environmental change and the ways in which we can manage and mitigate these impacts. They will explore sustainable practices in agriculture, energy use, and waste management, as well as the social, economic, and political factors that influence environmental decision-making.
Environmental science graduates have a broad range of career options, including working for government agencies, NGOs, and consulting firms. Environmental scientists may work as environmental consultants, conducting research and providing advice to businesses and government agencies on environmental policies and regulations. They may also work as conservation scientists, park rangers, or environmental educators. There is a growing demand for jobs in this field with new jobs arising constantly.
Throughout Units 1 and 2, students will engage in a range of activities, including fieldwork, data analysis, and research, to develop their scientific skills and deepen their understanding of environmental issues. By the end of the course, students will be equipped with the knowledge and skills to make informed decisions about their impact on the environment and to contribute to a sustainable future.
Environmental Science Units 3/4
Through Units 3 and 4, students will deepen their understanding of key environmental concepts and investigate the impacts of human activities on the environment, with a focus on sustainability.
In Unit 3, students will explore the impact of climate change on the environment, including the causes and consequences of global warming, strategies for mitigating its effects, and its impact on biodiversity. They will also investigate the role of human activities, such as agriculture and transportation, in contributing to climate change.
In Unit 4, students will deepen their understanding of environmental issues, investigating the factors that contribute to environmental change and the ways in which we can manage and mitigate these impacts. They will explore sustainable practices in agriculture, energy use, and waste management, as well as the social, economic, and political factors that influence environmental decision-making.
Environmental science graduates have a broad range of career options, including working for government agencies, NGOs, and consulting firms. Environmental scientists may work as environmental consultants, conducting research and providing advice to businesses and government agencies on environmental policies and regulations. They may also work as conservation scientists, park rangers, or environmental educators. There is a growing demand for jobs in this field with new jobs arising constantly.
Throughout Units 3 and 4, students will engage in a range of activities, including data analysis, research, and fieldwork, to deepen their understanding of environmental issues and develop their scientific skills. By the end of the course, students will be equipped with the knowledge and skills to make informed decisions about their impact on the environment and to contribute to a sustainable future.
ASSESSMENT
Assessment is comprised of coursework (class tests and practical work), practical investigation and examination.
Physics
Prerequisites
Physics Units 1 & 2 must be completed before Units 3 & 4.
Course Description
The study of Physics involves investigating, understanding and explaining the behaviour of physical phenomena in the Universe. Models, including mathematical models, are used to explore, simplify and predict how physical systems behave at varying scales from the very small (quantum and particle physics) through to the very large (astronomy and cosmology). Beginning with classical ideas and considering their limitations, and then being introduced to more modern explanations of the world, provides a novel lens through which students experience the world around them, drawing on their natural curiosity and wonder.
Each of the 4 units across Year 11 and 12 are structured under a series of curriculum-framing questions that reflect the inquiry nature of the discipline.
Unit 1: How is energy useful to society?
In this unit students examine some of the fundamental ideas and models used by physicists in an attempt to understand and explain energy. Models used to understand light, thermal energy, radioactivity, nuclear processes and electricity are explored. Students apply these physics ideas to contemporary societal issues: communication, climate change and global warming, medical treatment, electrical home safety and Australian energy needs.
Unit 2: How does physics help us to understand the world?
In this unit students explore the power of experiments in developing models and theories. They investigate a variety of phenomena by making their own observations and generating questions, which in turn lead to experiments. In Area of Study 1, students investigate the ways in which forces are involved both in moving objects and in keeping objects stationary and apply these concepts to a chosen case study of motion. A student-adapted or student-designed scientific investigation is undertaken in Area of Study 3.
Unit 3: How do fields explain motion and electricity?
In this unit students use Newton’s laws to investigate motion in one and two dimensions. They explore the concept of the field as a model used by physicists to explain observations of motion of objects not in apparent contact. Students compare and contrast three fundamental fields – gravitational, magnetic and electric – and how they relate to one another. They consider the importance of the field to the motion of particles within the field. Students examine the production of electricity and its delivery to homes. They explore fields in relation to the transmission of electricity over large distances and in the design and operation of particle accelerators.
Unit 4: How have creative ideas and investigation revolutionised thinking in physics?
In this unit, students explore some monumental changes in thinking in Physics that have changed the course of how physicists understand and investigate the Universe. They examine the limitations of the wave model in describing light behaviour and use a particle model to better explain some observations of light. Matter, that was once explained using a particle model, is re-imagined using a wave model. Students are challenged to think beyond how they experience the physical world of their everyday lives to thinking from a new perspective, as they imagine the relativistic world of length contraction and time dilation when motion approaches the speed of light. They are invited to wonder about how Einstein’s revolutionary thinking allowed the development of modern-day devices such as the GPS.
Psychology
Prerequisites
Psychology Units 1 & 2 are strongly recommended before Units 3 & 4.
Overview:
Psychology is a multifaceted discipline that seeks to describe, explain, understand and predict human behaviour and mental processes. It includes many sub-fields of study that explore and seek to better understand how individuals, groups, communities and societies think, feel and act.
VCE Psychology applies a biopsychosocial approach to the study of mental processes and behaviour. Within this approach, different perspectives, models and theories are considered to develop an understanding of human behaviour and mental processes and the interrelated nature of biological, psychological and social factors. Biological perspectives focus on how physiology influences individuals through exploring concepts such as hereditary and environmental factors, nervous system functioning and the role of internal biological mechanisms. Psychological perspectives consider the diverse range of cognitions, emotions and behaviours that influence individuals. Within the social perspective, factors such as cultural considerations, environmental influences, social support and socioeconomic status are explored. The biopsychosocial approach can be applied to understand a variety of mental processes and behaviours.
Course Description
Psychology Units 1/2
Semester 1 – How are behaviour and mental processes shaped – through the lens of Criminal Psychology?
In this unit students examine the complex nature of psychological development, including situations where psychological development may not occur as expected. Students examine the contribution that classical and contemporary knowledge from Western and non-Western societies, including Aboriginal and Torres Strait Islander peoples, has made to an understanding of psychological development and to the development of psychological models and theories used to predict and explain the development of thoughts, emotions and behaviours.
Students evaluate the role social cognition plays in a person’s attitudes, perception of themselves and relationships with others. Students explore a variety of factors and contexts that can influence the behaviour of individuals and groups, recognising that different cultural groups have different experiences and values. Students are encouraged to consider Aboriginal and Torres Strait Islander people’s experiences within Australian society and how these experiences may affect psychological functioning.
This semester culminates in students considering the question are criminals born or made?
Semester 2 – How do internal and external factors influence behaviour and mental processes?
Students examine the contribution that classical and contemporary research has made to the understandings of human perception and why individuals and groups behave in specific ways. Students investigate how perception of stimuli enables a person to interact with the world around them and how their perception of stimuli can be distorted. They investigate the structure and functioning of the human brain and the role it plays in mental processes and behaviour and explore brain plasticity and the influence that brain damage may have on a person’s psychological functioning
A student-adapted or student-designed scientific investigation is undertaken in Semester 2. The investigation involves the generation of primary data and is related to internal and external factors that influence behaviour and mental processes. The investigation draws on key knowledge and key science skills from across the course.
Psychology Units 3/4
Unit 3: Semester 1 – How does experience affect behaviour and mental processes?
In this unit students investigate the contribution that classical and contemporary research has made to the understanding of the functioning of the nervous system and to the understanding of biological, psychological and social factors that influence learning and memory.
Students investigate how the human nervous system enables a person to interact with the world around them. They explore how stress may affect a person’s psychological functioning and consider stress as a psychobiological process, including emerging research into the relationship between the gut and the brain in psychological functioning.
Students investigate how mechanisms of learning and memory lead to the acquisition of knowledge and the development of new and changed behaviours. They consider models to explain learning and memory as well as the interconnectedness of brain regions involved in memory. The use of mnemonics to improve memory is explored, including Aboriginal and Torres Strait Islander peoples’ use of place as a repository of memory.
Unit 4: Semester 2 – How is wellbeing developed and maintained?
In this unit students explore the demand for sleep and the influences of sleep on mental wellbeing. They consider the biological mechanisms that regulate sleep and the relationship between rapid eye movement (REM) and non-rapid eye movement (NREM) sleep across the life span. They also study the impact that changes to a person’s sleep-wake cycle and sleep hygiene have on a person’s psychological functioning and consider the contribution that classical and contemporary research has made to the understanding of sleep.
Students consider ways in which mental wellbeing may be defined and conceptualised, including social and emotional wellbeing (SEWB) as a multidimensional and holistic framework to wellbeing. They explore the concept of mental wellbeing as a continuum and apply a biopsychosocial approach, as a scientific model, to understand specific phobia. They explore how mental wellbeing can be supported by considering the importance of biopsychosocial protective factors and cultural determinants as integral to the wellbeing of Aboriginal and Torres Strait Islander peoples.
Scientific Investigation
A student-designed scientific investigation involving the generation of primary data related to mental processes and mental wellbeing is undertaken in either Unit 3 or Unit 4, or across both Units 3 and 4, and is assessed in Unit 4 Outcome 3. The design, analysis and findings of the investigation are presented in a scientific poster format
ASSESSMENT
Assessment is comprised of coursework and examination.