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 an authentic urban biodiversity management 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.

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 a synthetic biology project investigating genetically engineered organisms. Students will have the opportunity to develop higher level generic skills in computing, communication, critical analysis, problem solving, data analysis and experimental design.

World population is projected to reach 9 billion within 50 years and food production needs to double in a sustainable manner in order to feed human population. This profound challenge will be met by improving our knowledge and management of agroecosystems. This unit of study is designed to provide an introductory understanding of the biology and management of plants in dryland agroecosystems, with a focus on major Australian broad acre crops. Dryland agroecosystems can be defined as ecosystems modified for the purpose of producing crops, pastures and animals in environments where water limits productivity during part of the year (and are typical in Australian agriculture). These agroecosystems are characterised by regular agricultural interventions, such as cultivation, sowing, nutrient, weed, pest and disease management, and harvest. The program will involve developing an understanding of the interactions between the environment, crops/pastures and agricultural management in dryland agroecosystems. The model for describing and analysing agroecosystems will be centred on a typical cropping cycle, with an emphasis on cereals. You will gain knowledge and skills on crop physiological, growth and development responses to the combined climatic, edaphic, biotic and management factors in the growing environment. The unit will also provide a sound understanding and analysis of the practical farming framework in which this knowledge is applied through weed, disease and pest management, approaches to managing climate variability and precision agriculture. There will be a focus on assessing the effects of climate and weather in dryland agroecosystems, especially on understanding crop-water-nutrition relationships. Successful students will be able to appreciate and analyse the most important limitations to crop production and yield in Australia and how those limitations can be minimized or overcome through science-based planning and agronomic management practices.

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 practical stream. The content and nature of these components may vary from year to year.

Plants are fundamentally important to human food, fibre and energy requirements, but global productivity is reduced by an estimated 40% by pest (disease, insect and weed) pressures. The impact of these production losses is increasing as demand grows for greater food, fibre and energy production. This unit on Plant Protection focuses on the development and adoption of integrated crop management processes to control plant pathogens, insects and weeds. The advantages and disadvantages of biological, cultural, physical and chemical control methods are explored using examples from agro-ecosystems. You will develop a comparative case study of integrated pest management (IPM) for a particular crop that considers all three pest groups and present a seminar about this case study. You will learn the principles of healthy plant production, the ecology of diseases, insects and weeds and integrated approaches to manage these pests. Completing this unit of study will provide you with the skills required to identify important pest management issues and critically assess requirements for optimum intervention plans.

Our ever-changing world requires knowledge that extends across multiple disciplines. The ability to identify and explore interdisciplinary links is a crucial skill for emerging professionals and researchers alike. AGRI3888 presents the opportunity to bring together the concepts and skills you have learnt in your discipline and apply them to a real-world problem. For example, you will be part of an interdisciplinary student project team that investigates a real-world problem involving sustainable plant production in Australia. You will spend 2-5 days conducting fieldwork, observing and measuring production and related environmental attributes, and work collaboratively in a series of practical sessions (before and after the fieldwork) to digitally map crop and soil data, and to critically analyse all collected and mapped data. Each project group will then compile a 'consultant's report' for the landholder(s), detailing the issue or problem, the diagnosis and the recommended management strategies to optimize crop production/business returns, while protecting the environment. All of these skills are highly valued by employers. The fieldwork and practical sessions will be scaffolded with a series of lectures covering agronomy for legumes, cotton and pastures, along with irrigation and integrated pest management, and data requirements for site-specific crop management. You will foster the ability to work in interdisciplinary teams, which is essential for both professional and research pathways in the future.

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.

Plants are truly amazing. Plants lift water to heights that defy physics. Plants take sunlight and simple inorganic ingredients to create a bewildering diversity of organic compounds. What's even more amazing is that we are only just beginning to understand how plants achieve these amazing feats. This unit explores how plants function and illustrates how this knowledge can be applied to real-World problems. Major topics include how plants function as integrated systems, resource partitioning and the dilemmas faced by plants, interaction of plants with the world around them. Emphasis will be placed on integration of plant responses from molecular through to whole plant scales, and how this knowledge can be practically applied to maximise plant growth, optimise use of water and nutrients, and understand how plants affect (and are affected by) their environment. Lectures are augmented by experimental work that leads to practical hands-on experience with research tools and techniques that can be applied across the sciences, and bespoke instruments used in the world's leading plant science research laboratories. This unit of study complements other senior units of study in the Plant Science minor and is essential for those seeking a career in plant biology and plant-related fields, including ecology, cell biology, genetics, breeding, agriculture, molecular biology, environmental law, education and the arts.

This unit is designed to impart knowledge and skills in spatial analysis and geographical information science (GIS) for decision-making in an environmental context. The lecture material will present several modules: introduction to GIS, digital terrain mapping, remote sensing and applications. 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. 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 and written; and use a major GIS software package such as ArcGIS.

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 interdisciplinary unit provides students with the opportunity to address complex problems identified by industry, community, and government organisations, and gain valuable experience in working across disciplinary boundaries. In collaboration with a major industry partner and an academic lead, students integrate their academic skills and knowledge by working in teams with students from a range of disciplinary backgrounds. This experience allows students to research, analyse and present solutions to a real¿world problem, and to build on their interpersonal and transferable skills by engaging with and learning from industry experts and presenting their ideas and solutions to the industry partner.