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.

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.

The surface of the planet on which you live is the product of a balance between tectonic forces and numerous agents of erosion. The landscapes in which you live and work, and from which you draw resources, are therefore the legacy of many processes operating synchronously over long time periods. It is also true that Earth's landscapes are dynamic, and constantly changing around you in response to climate, tectonics and patterns of life. The sustainable management of landscapes is strongly dependent upon an awareness of those processes and the ways that they constrain human-environment interactions. In Earth Surface Processes, you will learn how landscapes are produced, and what this means for contemporary land use. Lectures by experts in physical geography, geology, soil science and environmental science will introduce you to the planetary and regional-scale controls on landforms and landscape dynamics, and the nature and distribution of major Australian landscape types. Focussed around 'hands on' field and laboratory-based tasks, students will gain essential practical, analytical and interpretive skills in the analysis of landscapes and earth surface processes that shape them. This is a unit for anyone wanting to better understand the planet on which they live.

The surface of the planet on which you live is the product of a balance between tectonic forces and numerous agents of erosion. The landscapes in which you live and work, and from which you draw resources, are therefore the legacy of many processes operating synchronously over long time periods. It is also true that Earth's landscapes are dynamic, and constantly changing around you in response to climate, tectonics and patterns of life. The sustainable management of landscapes is strongly dependent upon an awareness of those processes and the ways that they constrain human-environment interactions. In the Advanced mode of Earth Surface Processes, you will learn how landscapes are produced, and what this means for contemporary land use. Lectures by experts in physical geography, geology, soil science and environmental science will introduce you to the planetary and regional-scale controls on landforms and landscape dynamics, and the nature and distribution of major Australian landscape types. Focussed around 'hands on' field and laboratory-based tasks, students will gain essential practical, analytical and interpretive skills in the analysis of landscapes and earth surface processes that shape them. The Advanced mode of Earth Surface Processes challenges you to create new knowledge, and provides a higher level of academic rigour. You will take part in a series of small-group practical exercises that will develop your skills in research design and execution, and will provide you with a greater depth of understanding in core aspects of geomorphology. The Advanced mode will culminate in a research-focussed Advanced Assignment. This is a unit for anyone wanting to better understand the planet on which they live, and who may wish to develop higher-level analytical and research skills in geomorphology and landscape analysis.

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 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 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 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.