This is the gateway unit of study for Human Geography, Physical Geography, Environmental Studies and Geology. Its objective is to introduce the big questions relating to the origins and current state of the planet: climate change, environment, landscape formation, and the growth of the human population. During the semester you will be introduced to knowledge, theories and debates about how the world's physical and human systems operate. The first module investigates the evolution of the planet through geological time, with a focus on major Earth systems such as plate tectonics and mantle convection and their interaction with the atmosphere, hydrosphere, biosphere and human civilisations. The second module presents Earth as an evolving and dynamic planet, investigating global environmental change, addressing climate variability and human impacts on the natural environment and the rate at which these changes occur and how they have the potential to dramatically affect the way we live. Finally, the third module, focuses on human-induced challenges to Earth's future. This part of the unit critically analyses the relationships between people and their environments, with central consideration to debates on population change, resource use and the policy contexts of climate change mitigation and adaptation.

Advanced students will complete the same core lecture material as for GEOS1001, but will be required to carry out more challenging practical assignments.

Biology is an immensely diverse science. Biologists study life at all levels, from the fundamental building blocks (genes, proteins) to whole ecosystems in which myriads of species interact. Evolution is the unifying concept that runs through the life sciences, from the origin and diversification of life to understanding behaviour, to dealing with disease. Evolution through natural selection is the framework in biology in which specific details make sense. This unit explores how new species continue to arise while others go extinct and discusses the role of mutations as the raw material on which selection acts. It explains how information is transferred between generations through DNA, RNA and proteins, transformations which affect all aspects of biological form and function. Science builds and organises knowledge of life and evolution in the form of testable hypotheses. You will participate in inquiry-led practical classes investigating single-celled organisms and the diversity of form and function in plants and animals. By doing this unit of study, you will develop the ability to examine novel biological systems and understand the complex processes that have shaped those systems.

Biology is an immensely diverse science. Biologists study life at all levels, from the fundamental building blocks (genes, proteins) to whole ecosystems in which myriads of species interact. Evolution is the unifying concept that runs through the life sciences, from the origin and diversification of life to understanding behaviour, to dealing with disease. Evolution through natural selection is the framework in biology in which specific details make sense. This unit explores how new species continue to arise while others go extinct and discusses the role of mutations as the raw material on which selection acts. It explains how information is transferred between generations through DNA, RNA and proteins, transformations which affect all aspects of biological form and function. Science builds and organises knowledge of life and evolution in the form of testable hypotheses. You will participate in inquiry-led practical classes investigating single-celled organisms and the diversity of form and function in plants and animals.
Life and Evolution (Advanced) has the same overall structure as BIOL1006 but material is discussed in greater detail and at a more advanced level. Students enrolled in BIOL1906 participate in a research project with a focus on developing skills in critical evaluation, experimental design, data analysis and communication.

Biology is an immensely diverse science. Biologists study life at all levels, from the fundamental building blocks (genes, and proteins) to whole ecosystems in which myriad species interact. Evolution is the unifying concept that runs through the life sciences, from the origin and diversification of life to understanding behaviour, to dealing with disease. Evolution through natural selection is the framework in biology in which specific details make sense. Science builds and organises knowledge of life and evolution in the form of testable hypotheses. The practical work syllabus for BIOL1996 is different from that of BIOL1906 (Advanced) and consists of a special project-based laboratory.

Chemistry describes how and why things happen from a molecular perspective. Chemistry underpins all aspects of the natural and physical world, and provides the basis for new technologies and advances in the life, medical and physical sciences, engineering, and industrial processes. This unit of study will equip you with the fundamental knowledge and skills in chemistry for broad application. You will learn about atomic theory, structure and bonding, equilibrium, processes occurring in solutions, and the functional groups of molecules. You will develop experimental design, conduct and analysis skills in chemistry through experiments that ask and answer questions about the chemical nature and processes occurring around you. Through inquiry, observation and measurement, you will better understand natural and physical world and will be able to apply this understanding to real-world problems and solutions. This unit of study is directed toward students whose chemical background is weak (or non-existent). Compared to the mainstream Chemistry 1A, the theory component of this unit begins with more fundamental concepts, and does not cover, or goes into less detail about some topics. Progression to intermediate chemistry from this unit and Fundamentals of Chemistry 1B requires completion of an online supplementary course.

Chemistry describes how and why things happen from a molecular perspective. Chemistry underpins all aspects of the natural and physical world, and provides the basis for new technologies and advances in the life, medical and physical sciences, engineering, and industrial processes. This unit of study will further develop your knowledge and skills in chemistry for application to life and medical sciences, engineering, and further study in chemistry. You will learn about nuclear and radiation chemistry, wave theory, atomic orbitals, spectroscopy, bonding, enthalpy and entropy, equilibrium, processes occurring in solutions, and the functional groups in carbon chemistry. You will develop experimental design, conduct and analysis skills in chemistry through experiments that ask and answer questions like how do dyes work, how do we desalinate water, how do we measure the acid content in foods, how do we get the blue in a blueprint, and how do we extract natural products from plants? Through inquiry, observation and measurement, you will understand the 'why' and the 'how' of the natural and physical world and will be able to apply this understanding to real-world problems and solutions. This unit of study is directed toward students with a satisfactory prior knowledge of the HSC chemistry course.

Chemistry describes how and why things happen from a molecular perspective. Chemistry underpins all aspects of the natural and physical world, and provides the basis for new technologies and advances in sciences, engineering, and industrial processes. This unit of study will further develop your knowledge and skills in chemistry for broad application, including further study in chemistry. You will learn about nuclear and radiation chemistry, wave theory, atomic orbitals, spectroscopy, bonding, enthalpy and entropy, equilibrium, processes occurring in solutions, and the functional groups of molecules. You will develop experimental design, conduct and analysis skills in chemistry through experiments that ask and answer questions about the chemical nature and processes occurring around you. Through inquiry, observation and measurement, you will better understand natural and physical world and will be able to apply this understanding to real-world problems and solutions. This unit of study is directed toward students with a good secondary performance both overall and in chemistry or science. Students in this category are expected to do this unit rather than Chemistry 1A. Compared to the mainstream Chemistry 1A, the theory component of this unit provides a higher level of academic rigour and makes broader connections between topics.

Chemistry describes how and why things happen from a molecular perspective. Chemistry underpins all aspects of the natural and physical world, and provides the basis for new technologies and advances in the life, medical and physical sciences, engineering, and industrial processes. This unit of study will further develop your knowledge and skills in chemistry for application to life and medical sciences, engineering, and further study in chemistry. You will learn about nuclear and radiation chemistry, wave theory, atomic orbitals, spectroscopy, bonding, enthalpy and entropy, equilibrium, processes occurring in solutions, and the functional groups in carbon chemistry. You will develop experimental design, conduct and analysis skills in chemistry in small group projects. The laboratory program is designed to extend students who already have chemistry laboratory experience, and particularly caters for students who already show a passion and enthusiasm for research chemistry, as well as aptitude as demonstrated by high school chemistry results. Entry to Chemistry 1A (Special Studies Program) is restricted to a small number of students with an excellent school record in Chemistry, and applications must be made to the School of Chemistry. The practical work syllabus for Chemistry 1A (Special Studies Program) is very different from that for Chemistry 1A and Chemistry 1A (Advanced) and consists of special project-based laboratory exercises. All other unit of study details are the same as those for Chemistry 1A (Advanced).

This is an introductory statistics unit for students in the agricultural, life and environmental sciences. It provides the foundation for statistics and data science skills that are needed for a career in science and for further study in applied statistics and data science. In the first portion of the unit the emphasis is on describing data using statistical and graphical summaries, and probability models. In the second part the focus is on formal hypothesis testing on experimental data using statistical tests. The final part of the unit is on finding patterns in biological and environmental data, through the use of linear and non-linear functions. In the practicals the emphasis is on applying theory to analysing real datasets using the spreadsheet package Excel and the statistical software package R. A key feature of the unit is using R to develop coding skills that are become essential in science for processing and analysing datasets of ever increasing size.

In the 21st century the population of the world will increase both in size and its expectation in terms of food, energy and consumer demands. Against this demand we have a planet in crisis where natural resources are degraded, biodiversity is diminishing and planetary cycles related to climate are reaching points of irreversible change. Management of our precious natural resources is a balancing act between production and conservation as always, but now we have to do this against a background of potential large scale changes in climate. In this unit students will gain an understanding of the key environmental challenges of the 21st century; namely food security, climate change, water security, biodiversity protection, ecosystems services and soil security. In the second half using Australian case studies we will explore how we manage different agro-ecosystems within their physical constraints around water, climate and soil, while considering linkages with the global environmental challenges. Management now, in the past and the future will be considered, with an emphasis on food production. This unit is recommended unit for students interested in gaining a broad overview of the environmental challenges of the 21st century, both globally and within Australia.

This unit of study is designed to give an understanding of some basic economic principles and to introduce the characteristics of the economic environment in which Australian agriculture operates. Topics to be covered include the structure, nature and history of the agricultural industries in Australia; agricultural adjustment in the world economy; introductory principles of production economics and farm management; elementary price theory and the factors affecting the demand, supply and prices of agricultural commodities.

Paradigm shifts in biology have changed the emphasis from single biomolecule studies to complex systems of biomolecules, cells and their interrelationships in ecosystems of life. Such an integrated understanding of cells, biomolecules and ecosystems is key to innovations in biology. Life relies on organisation, communication, responsiveness and regulation at every level. Understanding biological mechanisms, improving human health and addressing the impact of human activity are the great challenges of the 21st century. This unit will investigate life at levels ranging from cells, and biomolecule ecosystems, through to complex natural and human ecosystems. You will explore the importance of homeostasis in health and the triggers that lead to disease and death. You will learn the methods of cellular, biomolecular, microbial and ecological investigation that allow us to understand life and discover how expanding tools have improved our capacity to manage and intervene in ecosystems for our own health and organisms in the environment that surround and support us . You will participate in inquiry-led practicals that reinforce the concepts in the unit. By doing this unit you will develop knowledge and skills that will enable you to play a role in finding global solutions that will impact our lives.

Paradigm shifts in biology have changed the emphasis from single biomolecule studies to complex systems of biomolecules, cells and their interrelationships in ecosystems of life. Such an integrated understanding of cells, biomolecules and ecosystems is key to innovations in biology. Life relies on organisation, communication, responsiveness and regulation at every level. Understanding biological mechanisms, improving human health and addressing the impact of human activity are the great challenges of the 21st century. This unit will investigate life at levels ranging from cells, and biomolecule ecosystems, through to complex natural and human ecosystems. You will explore the importance of homeostasis in health and the triggers that lead to disease and death. You will learn the methods of cellular, biomolecular, microbial and ecological investigation that allow us to understand life and discover how expanding tools have improved our capacity to manage and intervene in ecosystems for our own health and organisms in the environment that surround and support us . This unit of study has the same overall structure as BIOL1007 but material is discussed in greater detail and at a more advanced level. The content and nature of these components may vary from year to year.

Paradigm shifts in biology have changed the emphasis from single biomolecule studies to complex systems of biomolecules, cells and their interrelationships in ecosystems of life. Such an integrated understanding of cells, biomolecules and ecosystems is key to innovations in biology. Life relies on organisation, communication, responsiveness and regulation at every level. Understanding biological mechanisms, improving human health and addressing the impact of human activity are the great challenges of the 21st century. This unit will investigate life at levels ranging from cells, and biomolecule ecosystems, through to complex natural and human ecosystems. You will explore the importance of homeostasis in health and the triggers that lead to disease and death. You will learn the methods of cellular, biomolecular, microbial and ecological investigation that allow us to understand life and intervene in ecosystems to improve health. The same theory will be covered as in the advanced stream but in this Special Studies Unit, the practical component is a research project. The research will be either a synthetic biology project investigating genetically engineered organisms or organismal/ecosystems biology. Students will have the opportunity to develop higher level generic skills in computing, communication, critical analysis, problem solving, data analysis and experimental design.

Chemistry transforms the way we live. It provides the basis for understanding biological, geological and atmospheric processes, how medicines work, the properties of materials and substances, how beer is brewed, and for obtaining forensic evidence. This unit of study builds upon your prior knowledge of chemistry to further develop your knowledge and skills in chemistry for broad application. You will learn about organic chemistry reactions, structural determination, nitrogen chemistry, industrial processes, kinetics, electrochemistry, thermochemistry, phase behaviour, solubility equilibrium and chemistry of metals. You will further develop experimental design, conduct and analysis skills in chemistry through experiments that ask and answer questions about the chemical nature and processes occurring around you. Through enquiry, observation and measurement, you will better understand natural and physical world and will be able to apply this understanding to real-world problems and solutions. Fundamentals of Chemistry 1B is built on a satisfactory prior knowledge of Fundamentals of Chemistry 1A. Compared to the mainstream Chemistry 1B, the theory component of this unit begins with more fundamental concepts, and does not cover, or goes into less detail about some topics. Progression to intermediate chemistry from this unit requires completion of an online supplementary course.

Chemistry transforms the way we live. It provides the basis for understanding biological, geological and atmospheric processes, how medicines work, the properties of materials and substances, how beer is brewed, and for obtaining forensic evidence. This unit of study builds upon your prior knowledge of chemistry to further develop your knowledge and skills in chemistry for application to life and medical sciences, engineering, industrial processing, and further study in chemistry. You will learn about organic chemistry reactions, structural determination, nitrogen chemistry, industrial processes, kinetics, electrochemistry, thermochemistry, phase behaviours, solubility equilibrium and chemistry of metals. You will further develop experimental design, conduct and analysis skills in chemistry through experiments that ask and answer questions like how do we develop lotions that don't burn us, how do we measure UV absorption by sunscreens, how can we measure and alter soil pH, how are sticky things made, and how do we determine the concentration of vitamin C in juice? Through enquiry, observation and measurement, you will understand the 'why' and the 'how' of the natural and physical world and will be able to apply this understanding to real-world problems and solutions. Chemistry 1B is built on a satisfactory prior knowledge of Chemistry 1A.

Chemistry transforms the way we live. It provides the basis for understanding biological, geological and atmospheric processes, how medicines work, the properties of materials and substances, how beer is brewed, and for obtaining forensic evidence. This unit of study builds upon your prior knowledge of chemistry to further develop your knowledge and skills in chemistry for broad application, including further study in chemistry. You will learn about organic chemistry reactions, structural determination, nitrogen chemistry, industrial processes, kinetics, electrochemistry, thermochemistry, phase behaviour, solubility equilibrium and chemistry of metals. You will further develop experimental design, conduct and analysis skills in chemistry through experiments that ask and answer questions about the chemical nature and processes occurring around you. Through enquiry, observation and measurement, you will better understand natural and physical world and will be able to apply this understanding to real-world problems and solutions. Chemistry 1B (Advanced) is built on a satisfactory prior knowledge of Chemistry 1A (Advanced). Compared to the mainstream Chemistry 1B, the theory component of this unit provides a higher level of academic rigour and makes broader connections between topics.

Chemistry transforms the way we live. It provides the basis for understanding biological, geological and atmospheric processes, how food and medicines work, the properties of materials and substances. This unit of study builds upon your prior knowledge of chemistry to further develop your knowledge and skills in chemistry for application to life and medical sciences, engineering, industrial processing, and further study in chemistry. You will learn about organic chemistry reactions, structural determination, nitrogen chemistry, industrial processes, kinetics, electrochemistry, thermochemistry, phase behaviour, solubility equilibrium and chemistry of metals. You will develop experimental design, conduct and analysis skills in chemistry in small group projects. The laboratory program is designed to extend students, and particularly caters for students who already show a passion and enthusiasm for research chemistry, as well as a demonstrated aptitude. Chemistry 1B (Special Studies Program) is restricted to students who have gained a Distinction in Chemistry 1A (Special Studies Program) or by invitation. The practical work syllabus for Chemistry 1B (Special Studies Program) is very different from that for Chemistry 1B and Chemistry 1B (Advanced) and consists of special project-based laboratory exercises. All other unit of study details are the same as those for Chemistry 1B (Advanced).

This unit builds on introductory 1st year statistics units and is targeted towards students in the agricultural, life and environmental sciences. It consists of two parts and presents, in an applied manner, the statistical methods that students need to know for further study and their future careers. In the first part the focus is on designed studies including both surveys and formal experimental designs. Students will learn how to analyse and interpret datasets collected from designs from more than than 2 treatment levels, multiple factors and different blocking designs. In the second part the focus is on finding patterns in data. In this part the students will learn to model relationships between response and predictor variables using regression, and find patterns in datasets with many variables using principal components analysis and clustering. This part provides the foundation for the analysis of big data. In the practicals the emphasis is on applying theory to analysing real datasets using the statistical software package R. A key feature of the unit is using R to develop coding skills that are become essential in science for processing and analysing datasets of ever increasing size.

Microbes are essential for every aspect of life on the planet. Microbes in the human gut control our digestion and our immune system, microbes in the soil are required for plant growth, microbes in the ocean fix more carbon dioxide than all the earth's trees. This unit of study will investigate the diversity and activity of microorganisms - viruses, bacteria, fungi, algae and protozoa - and look at how they interact with us, each other, plants and animals. You will examine how microbes underpin healthy ecosystems through nutrient cycling and biodegradation, their use industrially in biotechnology and food production, and their ability to cause harm, producing disease, poisoning, pollution and spoilage. Aspects of microbial ecology, nutrition, physiology and genetics will also be introduced. This unit of study will provide you with the breadth of knowledge and skills needed for further studies of microbiology, and will provide the fundamental understanding of microbes that you will require if you specialise in related fields such as biochemistry, molecular biology, immunology, agriculture, nutrition and food sciences, bioengineering and biotechnology, ecology or science education.

Microbes are essential for every aspect of life on the planet. Microbes in the human gut control our digestion and our immune system, microbes in the soil are required for plant growth, microbes in the ocean fix more carbon dioxide than all the Earth's trees. In this unit of study you will investigate the diversity and activity of microorganisms - viruses, bacteria, fungi, algae and protozoa - and look at how they interact with us, each other, plants and animals. You will examine how microbes underpin healthy ecosystems through nutrient cycling and biodegradation, their use industrially in biotechnology and food production, and their ability to cause harm, producing disease, poisoning, pollution and spoilage. Detailed aspects of microbial ecology, nutrition, physiology and genetics will also be introduced. This unit of study will provide you with the breadth of knowledge and skills needed for further studies of microbiology, and will provide the fundamental understanding of microbes that you will require to specialise in related fields such as biochemistry, molecular biology, immunology, agriculture, nutrition and food sciences, bioengineering and biotechnology, ecology, or science education. As an Advanced unit, MICR2931 provides increased challenge and academic rigour to develop a greater understanding and depth of disciplinary expertise. You will actively participate in a series of small group tutorials investigating the molecular detail of microbial communication and function, which will culminate in you creating a scientific research report that communicates your understanding of recent research in microbiology.

This unit of study is designed to develop an understanding of the structural and molecular principles that underlie the function of plants and how these principles relate to the use of plants by humans as sources of food, fibre and fuel.
The unit is a core unit for BScAgr students and an elective for BSc and other degree programs. It recognizes the specialized nature of plant anatomy and biochemistry and is a platform for students who wish to gain a sound knowledge of plant growth and development.
This unit covers the structure of plant cells and the anatomy of the major tissues and organs of plants. It also covers the biochemistry of the main carbohydrate, lipid, protein and nucleic acid constituents of plants, as well as the metabolic pathways that regulate plant growth and development.
At the completion of this unit students will be able to demonstrate theoretical knowledge of the structure and function of plants. Students will also be able to demonstrate abilities in the practice of laboratory methods used to analyse plants and the effective communication of experimental findings.

Students enrolled in this unit will gain research and enquiry skills through attendance at lectures and participation in laboratory classes and tutorials; information literacy and communication skills through the synthesis of information used to prepare practical reports; social and professional understanding by participation in group-work and assessments that seek to demonstrate the role of agriculture in the broader community.

Soil and water are the two most essential natural resources on the Earth's surface which influence all forms of terrestrial life. This unit of study is designed to introduce students to the fundamental properties and processes of soil and water that affect food security and sustain ecosystems. These properties and processes are part of the grounding principles that underpin crop and animal production, nutrient and water cycling, and environmental sustainability. You will participate in a field excursion to examine soils in a landscape to develop knowledge and understanding of soil properties, water storage, water movement and cycling of organic carbon and nutrients in relation to food production and ecosystem functioning. At the end of this unit you will be able to articulate and quantify the factors and processes that determine the composition and behaviour of soil, composition of water, soil water storage and the movement of water on the land surface. You will also be able to describe the most important properties of soil and water for food production and sustaining ecosystem functions and link this to human and climatic factors. The field excursion, report and laboratory/computer exercises have been designed to develop communication, team work and collaborative efforts.

This unit of study is designed to develop the student's ability to critically examine and evaluate the production and management of animals used for food and fibre in Australia and internationally. The unit will focus on new and emerging issues in animal production, including productivity, welfare, remote monitoring and management, animals in the environment, and meeting specifications in an ever-evolving marketplace. The identification, selection and breeding of animals that are optimally suited to production systems is a focus. New thinking and innovations that are being used to address scientific, industry and social expectation challenges will be a feature of the unit and case studies will be used throughout to examine interactions between these factors and their impact on management practices. Students will gain research and inquiry skills through research based group projects, information literacy and communication skills through online discussion postings, laboratory reports and presentations, and personal and intellectual autonomy through working in groups. At the successful completion of the unit, students will have the core knowledge and skills to enable them to lead developments in production animal industries in Australia and overseas.

Plants grow across a range of environments, influencing form, function and ultimately reproductive success. Being sessile, plants lack the luxury of seeking an alternative 'stress-free lifestyle' and therefore rely on genetic and physical adaptations to survive and reproduce. To understand how a plant can achieve such flexibility requires knowledge of plant structure and the influence of environmental drivers on plant growth and function. In this unit, you will examine the physiological processes controlling plant growth and reproduction linked to environmental constraints. You will understand the relationship between tissue and cellular structure and their underlying role in physiological and metabolic activities, particularly processes involving light capture, photosynthesis, water regulation, nutrient management and metabolite redistribution. Lectures and interactive practicals will together introduce you to plant processes that underpin life on earth. Experimentation and analysis of plant physiological processes will develop a skill base that will lead to a greater understanding and appreciation of common plant processes. As a component of the Plant Science minor and the Plant Production major, BIOL2031 will provide an important platform to extend your interests in plant science and plant related fields across the curriculum.

Plants grow across a range of environments, which influence form, function and ultimately reproductive success. Being sessile, plants lack the luxury of seeking an alternative 'stress-free lifestyle' and therefore rely on genetic and physical adaptations to help survive and reproduce. To understand how a plant can achieve such flexibility requires an understanding of plant structure and the influence that environmental drivers have on plant growth and function. In this unit, you will examine the physiological processes controlling plant growth and reproduction linked to environmental constraints. You will understand the relationship between tissue and cellular structure and their underlying role in physiological and metabolic activities, particularly processes involving light capture, photosynthesis, water regulation, nutrient management and metabolite redistribution. Lectures and interactive practicals will together introduce you to plant processes that we commonly depend upon for food production, and plant related materials. Experimentation and analysis of plant physiological processes will develop a skill base that will lead to a greater understanding and appreciation of common plant processes that guide plant growth. As a component of the Plant Science minor, this unit will provide an important platform to extend your interests in plant science and plant-related fields, including ecology, cell biology, genetics, breeding, agriculture, molecular biology, environmental law, education and the arts. The advanced unit has the same overall concepts as BIOL2031 but material is discussed in a manner that offers a greater level of challenge and academic rigour. Students enrolled in BIOL2931 participate in alternative components, which include a separate lecture and practical stream. The content and nature of these components may vary from year to year.

Insects are the most abundant and diverse group of animals on earth; beetles alone account for 25% of animal life. Insects impact almost every facet of the ecosystem and our lives. Many insects play valuable and essential roles in pollinating different plant species, in predating and controlling insect pests and in recycling nutrients. Other insects are harmful and are the vectors for major diseases such as plague, malaria and recently emerged viral disease Zika. This unit will provide students with a broad introduction to entomology including insect evolution, ecology, anatomy and physiology. Students will learn applied entomological topics such as sustainable insect management in agricultural ecosystems, medical and veterinary entomology, insect-inspired technologies, and insects as a future food source for both livestock and humans. This theoretical background will be complemented by training in how to use and evaluate a range of identification tools such as lucid and traditional dichotomous keys that enable you to identify and classify major groups of insects. Practical classes will allow you to develop your identification, classification and preservation skills though examination of boxes of 'mystery insects' and through creating a museum-quality insect collection. Students will also learn procedures for caring and rearing live insects. By the end of the unit you will be well prepared to work in fields that require entomological skills.

The era of genomics has revolutionised our approach to biology. Recent breakthroughs in genetics and genomic technologies have led to improvements in human and animal health, in breeding and selection of economically important organisms and in the curation and care of wild species and complex ecosystems. In this unit, students will investigate/describe ways in which modern biology uses genetics and genomics to study life, from the unicellular through to complex multicellular organisms and their interactions in communities and ecosystems. This unit includes a solid foundation in classical Mendelian genetics and its extensions into quantitative and population genetics. It also examines how our ability to sequence whole genomes has changed our capacities and our understanding of biology. Links between DNA, phenotype and the performance of organisms and ecosystems will be highlighted. The unit will examine the profound insights that modern molecular techniques have enabled in the fields of developmental biology, gene regulation, population genetics and molecular evolution.

The era of genomics has revolutionised our approach to biology. Recent breakthroughs in genetics and genomic technologies have led to improvements in human and animal health, in breeding and selection of economically important organisms and in the curation and care of wild species and complex ecosystems. In this unit, students will investigate/describe ways in which modern biology uses genetics and genomics to study life, from the unicellular through to complex multicellular organisms and their interactions in communities and ecosystems. This unit includes a solid foundation in classical Mendelian genetics and its extensions into quantitative and population genetics. It also examines how our ability to sequence whole genomes has changed our capacities and our understanding of biology. Links between DNA, phenotype and the performance of organisms and ecosystems will be highlighted. The unit will examine the profound insights that modern molecular techniques have enabled in the fields of developmental biology, gene regulation, population genetics and molecular evolution. The Advanced mode of Genetics and Genomics will provide you with challenge and a higher level of academic rigour. You will have the opportunity to plan and carry out a project that will develop your skills in contemporary genetics/molecular biology techniques and will provide you with a greater depth of disciplinary understanding. The Advanced mode will culminate in a written report and in an oral presentation where you will discuss a recent breakthrough that has been enabled by the use of modern genetics and genomics technologies. This is a unit for anyone wanting to better understand the how genetics has shaped the earth and how it will shape the future.

This unit of study aims to give students an understanding of the properties of food constituents, and the interactions between these constituents during food processing, storage and digestion. The unit will develop an understanding of the relationship between form and functionality of constituents and the concept of fitness-for-purpose (i.e., quality) in converting agricultural products into foods. Students will gain an appreciation of the relationship between chemical composition and properties of macroconstituents (carbohydrates, proteins, lipids) and microconstituents (vitamins, minerals, antioxidants, flavour and anti-nutritional chemicals) and their functions in plant- and animal-based foods. The material presented in lectures and practical classes will enable students to develop research and inquiry skills and an analytical approach in understanding the biochemistry of foods, food processing and storage. On completing this unit, students will be able to describe the chemical and biochemical properties of major food constituents, and demonstrate an understanding of the functionality of these constituents in food processing and nutrition. Students will have gained experience in laboratory techniques used in industry for the analysis of some food products, and information literacy and communication skills from the preparation of practical reports.

This unit explores the impacts of microbes on plant productivity, food security and the management of natural environments. The lecture component discusses how microbes interact with plants at the ecosystem, whole plant, cellular and molecular levels, conditioning nutrient availability and acquisition, growth, yield, quality and environmental responses. The biology and epidemiology of plant-associated microbes, infection processes, colonisation strategies, plant responses and breeding for disease resistance will be discussed. The practical component introduces techniques used in handling, measuring and identifying plant-associated fungi and bacteria, diagnosis of plant disease and investigations of plant-microbe interactions, and develops skills in enquiry and problem solving through experimental design, execution and interpretation of data. Students learn to work in a research team, plan effective work schedules, work safely in a research laboratory with a range of scientific equipment, keep appropriate records, and use statistical analysis and simulations in research. The unit is core to the BScAgr degree and is available as an elective to BEnvSys and BSc students.

This unit of study is designed to provide a solid introductory understanding of the biology and management of cropping systems, with a focus on major Australian broad acre crops. The course examines a typical crop cycle, with an emphasis on cereals, especially wheat. An overview of the main crops grown in Australia is presented. The relationship between crop growth and soil and aerial environments is discussed, and the importance of water and water-use efficiency is highlighted. The physiology of crops--including germination, photosynthesis, vegetative and reproductive growth and development, transpiration, photosynthate partitioning, and mineral nutrient acquisition and use--is studied as the basis of crop yield and production. Biological processes associated with seed (grain) development are described. Weed management, pasture management, and precision agriculture are discussed in theoretical and practical terms, and an introduction to crop adaptation and breeding is presented. Successful students will attain the ability to appreciate and analyse some of the most important limitations to crop yield and production in Australia and how those limitations can be minimized or overcome through science-based planning and management practices.

This unit will familiarise students with the description and mapping of soil types in the Australian landscape, with common analytical methods for soil and with the various forms of degradation that may alter the quality and function of soil. It is an applied soil science unit that builds on the fundamental soil science concepts learned in the SOIL2003 unit. The first practical component of the unit, a five-day soil survey, will give students experience in soil description and classification in the field, and soil samples collected during this survey will be subsequently analysed for a variety of attributes by the students in laboratory practicals. In the lecture series, topics including soil type distribution, soil quality, soil function, soil fertility and soil degradation will be discussed and linked to practical sessions. By the end of this unit, students will be able to construct maps of soil properties and soil type distribution, describe primary soil functions, soil attributes and types of soil degradation in an agricultural context, and be able to recognize and communicate the ability of a soil profile to sustain plant growth. Students will gain research and inquiry skills by collecting, analysing and interpreting soil survey data, and will gain communication skills by having to prepare and present a poster.

This unit provides students with a direct contact with the agricultural reality of a developing country through a fieldtrip. Active learning in the field through contacts with farmers, public servants, cooperatives, private firms and NGOs should then motivate a critical reflection on the constraints to agricultural development in these environments.
The fieldtrip will be organized around central themes (for example, technology adoption, sustainable use of resources, access to credit, land use change) that will be introduced in a short series of seminars (held on main campus ahead of the departure and intended to provide a first introduction to some of the questions that are expected to be addressed in the field) and will constitute the focus of group work once back to main campus.
Although there are no formal prerequisites, the unit is directed to students that have completed most of the second year units in their degrees.
N.B. Department permission required for enrolment. Please note that, in practice, this unit will run prior to the start of semester 1 with all classes and the fieldtrip being scheduled during that period.

This unit of study provides a comprehensive programme on basic and applied aspects of male and female reproductive biology, with particular emphasis on livestock and domestic animals. The fundamental topics include reproductive cycles, sexual differentiation, gametogenesis, fertilization, embryo development, gestation and parturition. An understanding of the applications of advanced reproductive technologies is developed through lectures, tutorials and the assignments. In addition, practical instruction is given on semen collection and processing, manipulation of the reproductive cycle, artificial insemination, and pregnancy diagnosis in sheep and pigs. Classes are held at the Camperdown Campus in Sydney and at the Camden Campus Animal Reproduction Unit and Mayfarm piggery.

Animal Structure and Function A will develop an understanding of the role of the body systems in maintaining homeostasis in an animal's internal environment. In ASFA the structure and function of the musculoskeletal, cardiovascular, respiratory, urinary and integumentary systems of the body are explored in depth particularly with reference to the maintenance of homeostasis. The developed understanding of the normal functioning of these systems allows identification of the impact on the animal of abnormal function of these systems. A study of the structure and function of muscle will include its role in movement and as meat in a production setting. The overall goals of the Unit are (i) to enable students to develop a rich understanding of the relationships between body systems and structures (to be continued in ASFB). (ii) to develop generic skills particularly in group work and oral presentation,(iii) to develop an appreciation of the links between structure and function and their relevance to animal disease and production that will be further developed in Veterinary Pathogenesis as well as in advanced, applied studies in Behaviour in third year and in 4th year Animal Production.

This unit of study is concerned with the application of microeconomic principles to management decisions in agricultural, forest, and fisheries systems. The unit builds on the theoretical knowledge acquired in previous studies and introduces the methods of applied economic analysis through a range of topics including: production functions (single and multi-output), cost and profit functions; methods for the measurement of productivity; optimisation in biological production systems; and production under risk.

This unit builds on the concepts in microeconomics to provide insights into efficient and sustainable resource management. The primary focus of this unit is analytical. Emphasis is placed on the importance of property rights structures, cost-effective regulations and dynamic considerations in managing natural resource stocks and environmental assets. Some introductory material on economic valuation of environmental assets and benefit cost analysis is included.

A unit of study with lectures, practicals and tutorials on the application of recombinant DNA technology and the genetic manipulation of prokaryotic and eukaryotic organisms. Lectures cover the applications of molecular genetics in biotechnology and consider the regulation, impact and implications of genetic engineering and genomics. Topics include biological sequence data and databases, comparative genomics, the cloning and expression of foreign genes in bacteria, yeast, animal and plant cells, novel human and animal therapeutics and vaccines, new diagnostic techniques for human and veterinary disease, and the genetic engineering of animals and plants. Practical work may include nucleic acid isolation and manipulation, gene cloning and PCR amplification, DNA sequencing and bioinformatics, immunological detection of proteins, and the genetic transformation and assay of plants.

Qualified students will participate in alternative components of BIOL3018 Gene Technology and Genomics. The content and nature of these components may vary from year to year.

This unit will provide an introduction to the key issues involved in with the econometrics of cross-section and panel data. The topics this unit will cover include: instrumental variables; estimating systems by OLS and GLS; simultaneous equation models; discrete-choice models; treatment effects; and sample selection. Throughout the unit, emphasis will be placed on economic applications of the models. The unit will utilise practical computer applications, where appropriate.

This unit of study is designed to introduce students to the analysis of data they may face in their future careers, in particular data that are not well behaved. The data may be non-normal, there may be missing observations, they may be correlated in space and time or too numerous to analyse with standard models. The unit is presented in an applied context with an emphasis on correctly analysing authentic datasets, and interpreting the ouput. It begins with the analysis and design experiments based on the general linear model. In the second part, students will learn about the generalisation of the general linear model to accommodate non-normal data with a particular emphasis on the binomial and poisson distributions. In the third part linear mixed models will be introduced which provide the means to analyse datasets that do not meet the assumptions of independent and equal errors, for example data that is correlated in space and time. The units ends with an introduction to machine learning and predictive modelling. A key feature of the unit is using R to develop coding skills that are become essential in science for processing and analysing datasets of ever increasing size.

This unit of study covers topics on the production of high quality food from perennial fruit crops, wine grapes, vegetables. It also covers the key aspects of the postharvest handling and quality assurance of fresh produce. At the end of this unit students are expected to have a detailed understanding of these areas of horticultural food production and be able to discuss related literature and the physiological principles underlying the commercial success of these horticultural enterprises. Students will also gain research and enquiry skills through research based practical sessions and assignments.

Human population growth is causing irreversible change to almost all environments on earth. The extent of human change has been so great that a new geological epoch, the anthropocene, has been defined. Global warming, the introduction of pollutants and excessive use of nutrients are stressors affecting the biodiversity and resilience of ecosystems, and pose threats to human and environmental health. These human impacts carefully need to be monitored to guide appropriate management of urban, natural and agricultural systems. In this unit you will learn about transport pathways of pollutants, bioaccumulation, environmental toxicology (e.g., LD50 values), environmental monitoring and remediation techniques. Through lectures, laboratories and group work, concepts and methods of environmental monitoring will be illustrated and discussed including findings from the latest research. You will participate in structured practical exercises and field trips where you will apply sampling techniques, use bio-indicators and diversity indices to monitor ecosystem functioning. You will interpret the results and assess what the implications are for the ecological functioning and sustainable management of the environment. These hands-on exercises will be complemented with case-studies to guide you in critically analysing and evaluating environmental monitoring data. By taking this unit, you will acquire the necessary skills and knowledge in monitoring sites impacted by human activity.

The Unit is broadly divided into four sections, namely: estimating the nutritive characteristics of feeds; defining the nutrient requirements of animals; diet formulation; errors in feeding. The focus is on coming to an understanding of the assessment of nutritional adequacy and the avoidance and solving of nutritional problems, with a particular emphasis on animals used in agricultural production systems and wildlife. The principles discussed in this course will be expanded in the following year, in which species-specific systems will be described. The basis of successful feeding management is an understanding of the following: the composition of feeds; the digestibility and efficiency of utilisation of nutrients by the animal; the nutrient requirements of the animal; interactions between nutrients that influence health and production. And following from this, students will have the ability to formulate diets to meet animal requirements for a variety of purposes and under a variety of constraints; identify deficiencies, excesses and imbalances in diets and so avoid a decline in productive efficiency and/or a decline in health.

In this Unit students will complete the study of the structure and function of organ systems in animals started in ANSC3103. The role of the immune system will be investigated in relation to maintenance of internal homeostasis. An introduction to the nervous system and male and female reproductive anatomy and physiology will form the basis for further applied studies in these areas in third year Units of Study in Animal Health and Disease and Animal Reproduction. There will be development of the generic skills of critically reading and writing.

This unit focuses on the nature of agricultural and resource commodity markets, market demand relationships, market supply relationships, price determination under alternative market structures, marketing margin relationships, derived demand for inputs, spatially and temporally related markets, market dynamics, price expectations, commodity futures markets and other pertinent topics. Applied examples from the agricultural and resource industries and the overall economy will be used throughout the semester as illustrations of the principles involved.

Foundational concepts in welfare economics, such as economic efficiency, criteria for assessing social welfare improvements, and economic surplus measures, are analysed in detail and applied to project evaluation and policy assessment. Procedures of conducting a benefit-cost analysis are presented, and tools of non-market valuation for public goods and environmental assets are covered in detail. These techniques include both stated and revealed preference techniques, including contingent valuation, choice modeling, hedonic pricing and travel cost methods.

This unit builds on the principles of biological production economics and introduces optimisation methods to solve decision making problems encountered by agribusiness and natural resource firms and managers in public agencies. The principle focus is on the application of linear programming techniques, and students learn to consider solving decision making problems where the outcomes are not known with certainty, and where the timing of decisions is of essence.

This unit is designed to impart knowledge and skills in spatial analysis and geographical information science (GISc) for decision-making in an environmental context. The lecture material will present several themes: principles of GISc, geospatial data sources and acquisition methods, processing of geospatial data and spatial statistics. Practical exercises will focus on learning geographical information systems (GIS) and how to apply them to land resource assessment, including digital terrain modelling, land-cover assessment, sub-catchment modelling, ecological applications, and soil quality assessment for decisions regarding sustainable land use and management. A three day field excursion during the mid-semester break will involve a day of GPS fieldwork at Arthursleigh University farm and two days in Canberra visiting various government agencies which research and maintain GIS coverages for Australia. By the end of this UoS, students should be able to: differentiate between spatial data and spatial information; source geospatial data from government and private agencies; apply conceptual models of spatial phenomena for practical decision-making in an environmental context; apply critical analysis of situations to apply the concepts of spatial analysis to solving environmental and land resource problems; communicate effectively results of GIS investigations through various means- oral, written and essay formats; and use a major GIS software package such as ArcGIS.

This unit aims to develop a student's ability to undertake a major research project in an area of specialization. The unit builds on theoretical and applied knowledge gained across most of the units of study undertaken throughout their degree program. This unit is a corequisite with AFNR4102 and each student will work with an academic supervisor in an area of specialization and develop a well defined research project to be executed. The research project is undertaken to advance the students ability to build well-developed research skills, a strong analytical capacity, and the ability to provide high quality research results demonstrating a sound grasp of the research question. Working with an academic supervisor students will develop their ability to define a research project including the producing of testable hypotheses, identifying existing knowledge from reviewing the literature and the design and execution of a research strategy towards solving the research question. Students will build on their previous research and inquiry skills through sourcing a wide range of knowledge to solve the research problem and enhance their intellectual and personal autonomy by means of the development of experimental programs. Students will improve their written and planning skills by composing a research project proposal and the writing of a comprehensive literature review.

This unit of study is designed to allow students to critically reflect on the relationship between the rural enterprise and environment and how they can contribute to the future decisions and management affecting the rural community. It is a core unit of study in 4th year for the BAgrEc, BScAgr, BLWSc, BResEc, BHortSc which requires students to complete 40 days of professional experience with the expectation that students will examine the nature of facts from their degree in this environment. A minimum of 15 days must be completed on-farm/field. The remaining days may be at the student's discretion. The unit will be counted towards 4th year, but professional experience placements will normally be undertaken throughout the degree. In the early stages of the Professional Development program students participate in Faculty excursions that have been developed so they can experience a range of activities, such as research, extension, on-farm and industry both in the rural and urban environment to complement their learning within their individual degree programs. Building on this various workshops have been developed to assist students to identify a rural environment theme or issue of their interest with the specific emphasis being placed on them reflecting on how their new understandings of their theme of interest affects their personal and professional development. To complete this unit students will present a portfolio of their theme including critical reflection on the pivotal relationships between the academic degree, rural environment, professional experience, and beliefs and values if the rural community. Through developing these pivotal relationships, students will be able to use their new understandings to support and guide the future developments in the rural enterprise and environment. By developing and presenting the portfolio and engaging in other online activities the students will enhance their skills in inquiry, information literacy and communication. In particular the autonomous development of case studies reflecting the contemporary issues in agriculture and their professional placements the students will have to consider their understandings of ethical, social and professional issues and further develop the personal and intellectual autonomy.
Note: Department permission required for enrolment

This unit is a continuation of the major research project initiated in AFNR4101 and continues to build on theoretical and applied knowledge gained across most of the units of study undertaken throughout their degree program. Working with their academic supervisor in the area of specialization the student will continue to pursue the defined research project towards presenting final results and conclusions. The research results are presented in a format of a research paper as submitted to a research journal. The research paper and corrected literature review is combined and presented together as a thesis. Students will continue to build their research skills, develop strong analytical capacity, demonstrate a sound grasp of the topic, and an ability to interpret results in a broad framework. Working with an academic supervisor students will develop their ability to produce results of high quality, draw reliable conclusions and identify future areas avenues of research. Students will build on their previous research and inquiry skills through sourcing a wide range of knowledge to solve the research problem and enhance their intellectual and personal autonomy by means of the managing the research program. Students will improve their communication skills through oral presentation of their research findings, the production of a poster detailing their research findings and the writing of a research paper.

This unit of study is designed to expose students to the principles and practice of a diverse range of analytical methods used in life and environmental science. The unit of study will be presented in four modules including: materials and sampling techniques; separation techniques (chromatographic and electrophoretic); instrumentation and measurement techniques (spectral analyses); and microbiological and molecular biology techniques. Each module will be a combination of lectures and practical classes that will analyse common biological, agricultural or biochemical samples to illustrate the practical aspects of the theory. Students will also gain skills in data analysis relevant to the respective techniques.
At the completion of these modules, students will be familiar with the operation of a number of laboratory instruments, the theory that underpins their operation, be confident in the analysis of data, and be able to choose the most appropriate sampling strategy and analytical technique to perform high quality research.

Human population growth is causing irreversible change to almost all environments on earth. The extent of human change has been so great that a new geological epoch, the anthropocene, has been defined. Global warming, the introduction of pollutants and excessive use of nutrients are stressors affecting the biodiversity and resilience of ecosystems, and pose threats to human and environmental health. These human impacts carefully need to be monitored to guide appropriate management of urban, natural and agricultural systems. In this unit you will learn about transport pathways of pollutants, bioaccumulation, environmental toxicology (e.g., LD50 values), environmental monitoring and remediation techniques. Through lectures, laboratories and group work, concepts and methods of environmental monitoring will be illustrated and discussed including findings from the latest research. You will participate in structured practical exercises and field trips where you will apply sampling techniques, use bio-indicators and diversity indices to monitor ecosystem functioning. You will interpret the results and assess what the implications are for the ecological functioning and sustainable management of the environment. These hands-on exercises will be complemented with case-studies to guide you in critically analysing and evaluating environmental monitoring data. By taking this unit, you will acquire the necessary skills and knowledge in monitoring sites impacted by human activity.

This unit builds on the principles of biological production economics and introduces optimisation methods to solve decision making problems encountered by agribusiness and natural resource firms and managers in public agencies. The principle focus is on the application of linear programming techniques, and students learn to consider solving decision making problems where the outcomes are not known with certainty, and where the timing of decisions is of essence.

This unit of study is designed to provide an understanding of the underlying forces driving agricultural markets. It addresses price analysis and efficiency, including aspects of form, time and space in agricultural marketing; information and contracts; changing consumer concerns (food safety, ethical production); futures market and other risk sharing devices. Building on the application of microeconomic theory to both production and consumption in agricultural markets, its content is analytical. The unit also investigates some of the forces which prevent the efficient operation of world agricultural markets, including impediments to trade, imperfect markets for inputs and outputs and market power along the agricultural supply chain.

Lectures and practical work are devoted to the theory, philosophy and practice of plant breeding. The unit addresses screening techniques, conservation of genetic variability, breeding for disease resistance and integration of molecular technology in applied plant breeding, with examples from both field and horticultural crops. The unit is taught in the context [of] climate change, food security and the evolving global intellectual property environment.

This is a final year elective in the two degrees, BScAgr, and BAnVetBiosci. Approximately a half of the face-to-face contact hours will be given as an intensive, and this section of the unit will be held during the mid-year break before semester 2. Lecture and practical work in cytogenetics, especially of plant and animal species of applied interest in plant agriculture, animal agriculture and other applied interest in animal genetics, such as companion, native and endangered species. The lecture component covers the molecular nature of chromosomes and their transmission, variation in chromosome behaviour, both normal and disease related. In addition, the uses of chromosome engineering to produce variation in plants and animals will also be covered. The practical component covers the technologies used to study chromosomes or both plants and animals, both mitotic and meiotic chromosomes, and molecular techniques such as in situ hybridisation, gene activity and chromosomal protein localisation. On completion, students will be able to apply cytogenetic knowledge and technologies to species of eukaryotes of economic significance, and know how cytogenetic processes have affected the development of these species.

This unit examines agronomy as the discipline that underpins agricultural production. As a case study, the cotton industry is examined in detail to understand the end-user and social demands on agricultural production, the technical issues that challenge the farmer and the diversity of other specialist information from relevant disciplines such as entomology, pathology and soil science that must be integrated into the farming system. The unit also covers precision agriculture, legume science, rangeland science and crop protection. This unit includes a one-week excursion to cotton growing areas in northern NSW and Qld, specialist intensive instruction provided by the Cotton RDC, and a series of workshops, tutorials that provides analysis and synthesis of the major farming systems in this industry. Pasture production is also considered in the context of farming systems.

This unit is designed to provide students with training in the professional skills required to practice agronomy. The unit principally builds on theoretical and applied knowledge gained in third year agronomy (AGRO3004). In this unit students will integrate their knowledge of plant physiology, soil science, experimental design, and biometry to address applied problems in agronomy, namely the issue of sustainability. Students will develop their ability to establish conclusions towards making recommendations for long term sustainability of crop and pasture systems. By implementing and managing a major field and/or glasshouse experiment(s) students will develop their research and inquiry skills. Team work is strongly encouraged in this unit and the integration and reporting of research findings will facilitate critical thinking and development of written communication skills. After completing this unit, students should be able to confidently design and manage a glasshouse/field experiment, and interpret and communicate their findings, by integrating knowledge from across disciplinary boundaries.

This unit examines livestock production following a whole system approach by integrating animals, vegetation, environment (soil, water, air and climate) and management, and analysing the interactions between them. The unit builds on principles delivered in core (AGEN1001, AGEN1004 and AGEN2006) and elective (ANSC3101, AVBS4012) units of study for those students interested in pursuing a career in Animal Science. The focus of this unit is on farm business planning and consulting for beef cattle and sheep. Particularities and commonalities of these livestock systems will be presented.
The pasture/grassland section examines the relationship between livestock production, forage quality and quantity in both native and sown pastures, impact of weeds, and grazing management. Interactions between climate, forage and animal production are also addressed. The animal component of this unit integrates concepts in grazing ecology, nutrition, reproduction, animal behaviour and welfare, and economics to develop skills in managing the production process for improved productivity, production efficiency and environmental stewardship. A special characteristic of this unit is the strong focus on simulation models, decision support systems, and new technologies. Computer-based and field classes will provide direct experience in business management of livestock production systems and skills in record keeping and data handling. Students completing this unit will acquire skills to examine and manage livestock enterprises following a whole-system approach required in roles as consultants, advisors or managers of sustainable livestock enterprises.

This unit of study is designed to provide students with an advanced understanding of new and emerging livestock technologies in Australia and overseas. Examples of these technologies include (1) next-generation infrared and laser scanning to determine physiological status and whole body composition, (2) diet formulation to enhance the nutritional and eating quality of livestock food products, (3) new vaccines and other therapeutics to regulate fertility, growth and behaviour whilst enhancing welfare and wellbeing, (4) microRNA technology to influence cellular, endocrine and physiological processes, (5) new genomics and laboratory-based reproductive technologies for advanced livestock breeding, (6) technologies to monitor and control animal behaviour, (7) unmanned ground and aerial vehicles to monitor livestock and the environment, (8) sensors and advanced image-capture technology to record the attributes of soil, air and the feedbase, (9) data-fusion science to integrate, analyse and interpret collected data, and (10) modelling of livestock systems. Students will gain research and inquiry skills through research based group projects, information literacy and communication skills through on-line discussion postings, laboratory reports and presentations, and personal and intellectual autonomy through working in groups. At successful completion of the unit students will have a sound knowledge of new and emerging technologies that will shape the livestock industries in Australia and overseas. This will provide valuable grounding for students preparing for postgraduate study and other learning and career paths.

Knowledge of the evolutionary relationships between insect groups contributes to our understanding of insect biology and correct taxonomic identification of insects is essential for all areas of entomological research, including pest management. This unit builds on the knowledge gained in second year entomology (BScAgr and BHortSc) and is a core unit for the entomology specialisation (BScAgr). Key concepts that underpin the study of insect systematics, biogeography and phylogeny are described using examples from the evolutionary development of insects. The role of morphological, genetic and molecular studies in the classification of insects is examined. Students will demonstrate their knowledge of insect taxonomy through individual projects. Students will have the opportunity to become `experts¿ on a self-selected insect order.Students will practice their communication skills and develop personal and intellectual autonomy through in-class discussions and presentations Students will see insect taxonomy in actino through field trips to museums, laboratories and hospitals.

The focus of this unit is the development and adoption of sustainable integrated pest management (IPM) within Australian (and global) agriculture. It builds on the knowledge gained in second year entomology (BScAgr) and is a core unit for the entomology specialtisation (BScAgr). Applied entomology deals with the sustainable control of insect pests using a variety of techniques such as biological control and habitat manipulation. Students will compare the advantages and disadvantages of different pest control strategies and evaluate the importance of insect ecology, control methods and socio-economic factors to successful adoption of integrated pest management. Field trips will demonstrate the practical application of IPM concepts presented in lectures. Research, inquiry and information literacy skills will be improved through critical review of current literature and compilation of a case study. Students will practice their communication skills and develop personal and intellectual autonomy through a group project and in-class discussion.

In order to obtain a deeper understanding of statistics it is necessary to learn more about matrices as used to develop and explain statistical and mathematical concepts. Matrices are not just used in statistics: they find use in mathematical models in biology (e.g. age structured population growth models), engineering (e.g. structural perturbation analysis), and economic models (e.g. decision analysis). There are three aims to this unit. Firstly, we will revise matrices learnt in earlier units and then introduce new concepts such as special matrices (symmetric, orthogonal, idempotent), rank, eigenvalues and eigenvectors, as well as some matrix and vector calculus. The second aim is to apply these techniques to the formulation of linear models and linear mixed models which have been introduced in earlier units. The underlying theory will be developed along with more advanced applications. The third aim is to provide an introduction to key application areas for the future; (i) the analysis of big datasets, ones with many predictor variables, and (ii) the analysis of spatial data. Furthermore, the students will be introduced to R, an open source statistical software package.

This unit consists of 3 components; multivariate statistics, sample designs and generalized linear models. In the first part principal component analysis and multivariate analysis of variance (MANOVA) will be covered. In the second part basic sample designs such as simple random, stratified random, ratio estimation and cluster sampling will be covered. Finally generalized linear models will be introduced with more theoretical detail than is taught in earlier units. Research skills will developed by project work involving the analysis of a real world dataset from a relevant discipline.

This unit introduces students to essential statistical and mathematical theory that should be at the fingertips of practising statisticians. Topics include a comprehensive review of statistical distributions and their properties; including the binomial, Poisson, geometric, normal and exponential distributions. In addition techniques such as method of moments and maximum likelihood estimation will be introduced for fitting the distributions to the data will be explored. Research skills will developed by project work involving the analysis of a real world dataset.

This unit of study is aimed at advanced techniques in Remote Sensing (RS), linked with Geographical Information Systems (GIS), as applied to land management problems. We will review the basic principles of GIS and then focus on advanced RS principles and techniques used for land resource assessment and management. This will be followed by practical training in RS techniques, augmented by land management project development and implementation based on integration of GIS and RS tools. The unit thus consists of three separate but overlapping parts: 1) a short theoretical part which focuses on the concepts of RS; 2) a practical part which aims at developing hands-on skills in using RS tools, and 3) an application-focused module in which students will learn the skills of how to design a land management project and actualize it using integrated GIS and RS techniques.

From the grinding of grains to the drying of meats, humans have been processing their food since the dawn of civilisation. Over the decades, many traditional processing methods have become industrialised, while new processing technologies have emerged, quietly revolutionising our food systems, diets and cultures. In this unit of study, students examine the biochemical and physicochemical transformations that occur in food materials during processing and how processing parameters affect the fulfilment of food quality, shelf-life, and safety objectives. The unit is roughly organised into modules on (1) processing to modify food structure; (2) processing for preservation; and value-adding, focused on (3) healthier food and (4) fermentation as interesting case studies in food processing.The unit will include lectures, laboratory sessions, group work and visits to food processing facilities.

This Unit of Study provides students with a scientific grounding in the sustainable production of safe and nutritious fruit, vegetables and mushrooms. The unit encompasses the fundamentals of production system options, resource management and marketing practices. Case studies will be used to exemplify important developments in horticultural production, supply and marketing chains. Students will examine multiple real world examples of horticulture to develop skills in systematic problem-solving in production and marketing. Combining relevant industry knowledge, critical analytical skills, and a systems perspective will enable students to make valid, scientifically-informed decisions in horticulture and beyond. The unit is comprised of: lectures/workshops, practicals in production and post-harvest horticulture, and site visits to producers, research sites and industry bodies. The program includes a week-long field trip to major horticultural production regions to view operations and Q and A with owner/operators.

This unit of study is intended to describe fundamental scientific knowledge relating to fire behaviour and ecological and social effects of bushfire in Australian ecosystems. The student will gain a greater understanding of how fire has shaped the landscape and the people. It is an elective unit that builds on basic knowledge gained in junior-level biology and chemistry and intermediate-level plant biology and soil science subjects. Firstly, fire behaviour including the elements of weather, fuel and landscape will be explained and examined in relation to predictive modelling and climate change. Secondly, the fire response of flora, fauna, fungi and microorganisms will be described at a range of different scales and analysed against a background of current land management practices in Australia. Social aspects of bushfire will be discussed and analysed according to contemporary policies and practices. At the end of this unit, students will be able to apply fire behaviour and ecological principles for planning purposes and to integrate scientific information from a range of sources to assess fire impacts on the environment and human communities. The students will gain research, literacy and communication skills through field-based data collection, essay and report writing and oral presentations.

This unit of study enables students to understand the management and conservation of trees and forests in a changing climate. It is an elective unit for students enrolled in advanced topics for the Bachelor of Environmental Systems course program. Beginning with an introduction to the unique chemical, physical and ecological characteristics of trees, this unit then focuses on policy development and management prescriptions driven by fundamental processes of ecosystem function. At the end of this unit students will be able to articulate critical evaluations of scientific and policy based documents in relation to research and management of trees in the Australian landscape. Students will be given the opportunity to gain firsthand knowledge of Australian forest management by participating in a two day field excursion (in week 6 of semester) combined with industry, government, research and conservation groups. At the end of this unit, students will be able to articulate strengths, weaknesses and improvements to the management of Australian forests for the purposes of production, conservation and climate change adaptation. Students will gain an intricate knowledge of tree function and be able to relate this understanding to the management of trees and forests in a changing environment. Students will develop skills to enable effective communication with industry, conservation and governmental groups.

This unit of study covers topics on the production of high quality food from perennial fruit crops, wine grapes, vegetables. It also covers the key aspects of the postharvest handling and quality assurance of fresh produce. At the end of this unit students are expected to have a detailed understanding of these areas of horticultural food production and be able to discuss related literature and the physiological principles underlying the commercial success of these horticultural enterprises. Students will also gain research and enquiry skills through research based practical sessions and assignments.

This Unit of Study provides students with a scientific grounding in the sustainable production of safe and nutritious fruit, vegetables and mushrooms. The unit encompasses the fundamentals of production system options, resource management and marketing practices. Case studies will be used to exemplify important developments in horticultural production, supply and marketing chains. Students will examine multiple real world examples of horticulture to develop skills in systematic problem-solving in production and marketing. Combining relevant industry knowledge, critical analytical skills, and a systems perspective will enable students to make valid, scientifically-informed decisions in horticulture and beyond. The unit is comprised of: lectures/workshops, practicals in production and post-harvest horticulture, and site visits to producers, research sites and industry bodies. The program includes a week-long field trip to major horticultural production regions to view operations and Q and A with owner/operators.

This unit of study is designed to allow students to examine advanced hydrological modeling focusing on catchment level responses and uncertainty. Students will learn how to develop their own simulation model of catchment hydrological processes in R and using SWAT and review the possibilities and impossibilities of using simulation models for catchment management. Students will further investigate landuse change impacts and climate change impacts the variability in hydrological responses. At the end of this unit, students will be able to calibrate and evaluate a catchment model, articulate advantages and disadvantages of using simulation models for catchment management, justify the choice of a simulation model for a particular catchment management problem, identify issues in relation to uncertainty in water quality and quantity The students will gain research and inquiry skills through research based assignments, information literacy and communication skills through laboratory reports and a presentation and personal and intellectual autonomy through working in groups.

This unit is designed to impart knowledge and skills in spatial analysis and geographical information science (GISc) for decision-making in an environmental context. The lecture material will present several themes: principles of GISc, geospatial data sources and acquisition methods, processing of geospatial data and spatial statistics. Practical exercises will focus on learning geographical information systems (GIS) and how to apply them to land resource assessment, including digital terrain modelling, land-cover assessment, sub-catchment modelling, ecological applications, and soil quality assessment for decisions regarding sustainable land use and management. A three day field excursion during the mid-semester break will involve a day of GPS fieldwork at Arthursleigh University farm and two days in Canberra visiting various government agencies which research and maintain GIS coverages for Australia. By the end of this UoS, students should be able to: differentiate between spatial data and spatial information; source geospatial data from government and private agencies; apply conceptual models of spatial phenomena for practical decision-making in an environmental context; apply critical analysis of situations to apply the concepts of spatial analysis to solving environmental and land resource problems; communicate effectively results of GIS investigations through various means- oral, written and essay formats; and use a major GIS software package such as ArcGIS.

This is a theoretical and empirical unit providing specialised training in three important areas of contemporary soil science, namely pedology, soil chemistry and soil physics. The key concepts of these sub-disciplines will be outlined and strengthened by hands-on training in essential field and laboratory techniques. All of this is synthesized by placing it in the context of soil distribution and use in North-Western New South Wales. The unit is motivated by the teaching team's research in this locale. It builds on students, existing soil science knowledge gained in SOIL2003. After completion of the unit, students should be able to articulate the advantages and disadvantages of current field and laboratory techniques for gathering necessary soil information, and simultaneously recognise key concepts and principles that guide contemporary thought in soil science. Students will be able to synthesise soil information from a multiplicity of sources and have an appreciation of the cutting edge areas of soil management and research. By investigating the contemporary nature of key concepts, students will develop their skills in research and inquiry. Students will develop their communication skills through report writing and will also articulate an openness to new ways of thinking which augments intellectual autonomy. Teamwork and collaborative efforts are encouraged in this unit.

This is a problem-based applied soil science unit addressing the physical, chemical and biological components of soil function. It is designed to allow students to identify soil-related problems in the real-world and by working in a group and with an end-user, to suggest short and long-term solutions to problems such as fertility, resilience, carbon management, structural decline, acidification, salinisation and contamination. By designing and administering strategies to tackle real-world soil issues, students will develop their research and inquiry skills and enhance their intellectual autonomy. By producing reports and seminars that enables understanding by an end-user, students will improve the breadth of their communication skills. This is a core unit for students majoring or specialising in soil science and an elective unit for those wishing to gain an understanding of environmental problem-solving. It utilises and reinforces soil-science knowledge gained in SOIL2003 and SOIL2004, as well as generic problem-solving skills gained during the degree program.

The Unit of Study explores in detail aspects of commercial aquaculture, including global trends in aquaculture development. Other topics include water quality, feeding, management, health and disease, genetics and reproduction, environmental impact and economic constraints to production. The unit of study emphasises methods to improve aquacultural productivity. It builds on basic principles of anatomy, physiology, nutrition, genetics and health and disease presented in other units of study in BAnVetBioSc. At the end of this Unit of Study, students will demonstrate an understanding of the principles of: the context of aquaculture in global food production; husbandry, management and welfare of aquaculture species; comparative aspects of husbandry in aquaria, domestic, commercial; health and disease relevant to aquaculture; nutrition of aquaculture species; reproduction and genetics of species in aquaculture; water quality and environmental impact of aquaculture; economics and marketing of aquaculture products.

This unit introduces the concepts of sheep (wool and meat) and beef cattle production in the Australian environment within the context of world food and fibre consumption and production. The key products as well as domestic and export markets for these are presented. The course provides an historical perspective of the basis for each of these industries and describes each of the production systems designed to meet the demand for these products.
Production in both the tropical and temperate regions of Australia will be covered and include the key elements of extensive grazing and intensive feedlot systems. Major issues will include breeds and breeding systems, basic nutrition and production practices and animal welfare issues as they affect the quality and quantity of product marketed.
The concepts of first stage processing of both meat and fibre products in abattoirs and top-making plants respectively will be presented. The major factors that influence the quality of product and therefore grading and market demand will be presented.
Lecture material will be supported with appropriate practical classes and a 5 day study tour to the Riverina to evaluate different commercial production systems. Students will also have an opportunity to compete in the annual Inter Collegiate Meat Judging (ICMJ) competition as a member of the University of Sydney team. This competition involves teams from numerous universities throughout Australia as well as Japan and the USA.

Viruses are some of the simplest biological machinery known yet they are also the etiological agents for some of the most important human diseases. New technologies that have revolutionised the discovery of viruses are also revealing a hitherto unappreciated abundance and diversity in the ecosphere, and a wider role in human health and disease. Developing new gene technologies have enabled the use of viruses as therapeutic agents, in novel vaccine approaches, gene delivery and in the treatment of cancer. This unit of study is designed to introduce students who have a basic understanding of molecular biology to the rapidly evolving field of virology. Viral infection in plant and animal cells and bacteria is covered by an examination of virus structure, genomes, gene expression and replication. Building upon these foundations, this unit progresses to examine host-virus interactions, pathogenesis, cell injury, the immune response and the prevention and control of infection and outbreaks. The structure and replication of sub-viral agents: viroids and prions, and their role in disease are also covered. The practical component provides hands-on experience in current diagnostic and research techniques such as molecular biology, cell culture, serological techniques, immunofluorescence and immunoblot analyses and is designed to enhance the students' practical skills and complement the lecture series. In these practical sessions experience will be gained handling live, potentially pathogenic microbes. Tutorials cover a range of topical issues and provide a forum for students to develop their communication and critical thinking skills. The unit will be taught by the Discipline of Microbiology within the School of Life and Environmental Sciences with the involvement of the Discipline of Infectious Diseases and Immunology within the Sydney Medical School.

This unit of study aims to promote understanding of Indigenous knowledge of land and food both past and present, and develop skills in identifying and developing opportunities for Indigenous engagement in land management and food production. It is an elective unit of study for undergraduate degree students in Science, Business and Arts; and for Honours and Masters degree students in Science and Arts.
This unit of study will explore the importance of the Indigenous estate (the 20-25% of Australia which is under some form of Indigenous land tenure) and will examine Indigenous knowledge to engage with contemporary realities of land management and food production for the sustainability of communities living on country. Emphasis will be on identifying opportunities for economic activities based on land and food management for the communities visited on the field trip.
Students will describe traditional land and food knowledge and understand the complex situation around living on country and the long term trends that are impacting on Indigenous communities. They will participate in activities with community members to identify opportunities for the development of enterprises based on land and food knowledge, then design and develop a plan for an activity that could contribute to the sustainability of the community.
Students will develop cultural competency through engagement with indigenous communities and recognition of the influence of their personal and cultural background through self-reflection. They will develop social research skills in collection and interpretation of qualitative data and the ability to describe a complex social/cultural ecological system and design interventions to improve problem situations. It will also provide students with skills and ideas for future research projects that will engage Indigenous communities and improve partnerships and dialogue.

This unit of study will develop knowledge, skills and understanding for engaging effectively with the people whose decisions shape innovation in agricultural production and environmental management. The role of extension in agricultural and environmental management is a crucial aspect of sustainability, as extension agents provide the main conduit between scientists, economists and policymakers and the people who live and work in the landscape.
It develops key graduate competencies in communication and soft systems for careers including consulting, agribusiness, agricultural extension, environmental management, policy, participatory research and natural resource management. It covers integrative aspects of extension theory and practice, social learning, sustainable agriculture, knowledge domains, participatory action research, human geography, soft systems thinking and adaptive natural resource management. It is relevant to students pursuing agricultural and environmental streams and majors at both undergraduate and postgraduate level.
Students will learn to: describe and discuss the theoretical and practical underpinnings of extension; describe and analyse factors influencing the behaviours, attitudes and beliefs of natural resource managers; discuss and design effective extension programs/projects; conduct, analyse and evaluate simple surveys, focus groups and semi-structured interviews; critically evaluate the integration of conservation and production in the landscape; facilitate sustainable change.

Animal Genetics ANSC3107 is an exciting course that explores the technologies used by geneticists in practical situations involving domestic animals. We will expand on concepts learned in GENE2001 to learn more about genome sequencing, variant discovery, phylogenomics, bioinformatics, epigenetics, association mapping, gene therapy and forensic genetics.

This unit will explore the various aspects of dairy farming and the dairy industry from a scientific point of view. The lectures are a mix of the principles on which sound dairy farming is based and practical examples of how this operates in practice. Focus is placed on integrating knowledge to gain understanding on the system of production as a whole. At the end of this unit of study, students will demonstrate a solid understanding of: the characteristics of the dairy industry in Australia and in a world wide context; the key components of pasture-based dairy systems; principles and practices of pasture and feeding management; the application of new technologies to improve efficiency and productivity (particularly automatic milking). In addition, students will demonstrate an appreciation of key aspects of reproduction and lactation physiology; the integration of knowledge of genetics and reproduction into the type of herd improvement structure set up in the dairy industry; the application of ruminant physiology knowledge to developing feeding programs for dairy cows; the extension of basic reproductive physiology onto the dairy farm using case studies as examples; the economics of the dairy farm business. Practical classes include milking cows; grazing and feeding management of dairy cows; calf rearing; and visits to commercial farms ranging from small pasture-based dairy farms to a feed-lot operation milking over 2,000 cows.

This unit of study is composed of two parts, a Poultry Production component and a Pig Production component. The course will provide students with a comprehensive overview of the production of eggs and poultry meat and pork. The individual components examine various aspects of the poultry and pig production systems important in maintaining efficiency and profitability. It investigates aspects of breeding, nutrition, housing, growth performance, heath, welfare, reproductive capability, waste management, marketing and current industry issues. This unit will expand on some aspects of previous year 3 units of study in animal structure and function, nutrition and reproduction. There is a broiler growth study which comprises a significant part of the practical work in the Poultry component. There is a strong emphasis on assessment being built into the course work as this is considered to be more relevant to learning in the final year.