Marine conservation planning for persistent coral reef communities: Incorporating connectivity and resilience. Australia's biological diversity underpins much of our economic wealth - for example the remarkable diversity of coral reefs fuels a multibillion dollar tourism industry. However, despite substantial efforts to conserve marine ecosystems, Australian coral reefs are at increasing risk from climate change related catastrophes. To counteract this trend, we must choose marine reserve networ ....Marine conservation planning for persistent coral reef communities: Incorporating connectivity and resilience. Australia's biological diversity underpins much of our economic wealth - for example the remarkable diversity of coral reefs fuels a multibillion dollar tourism industry. However, despite substantial efforts to conserve marine ecosystems, Australian coral reefs are at increasing risk from climate change related catastrophes. To counteract this trend, we must choose marine reserve networks using methods that account for the dynamic nature of climate change and reef community responses to maximise the persistence of reef biodiversity. The new theory and methods will enable us to create more effective and economically efficient marine reserve systems.Read moreRead less
Coral reef connectivity: an empirical and theoretical synthesis. Australia possesses the greatest marine biodiversity of any first world country and this biodiversity is a major contributor to our economic wealth. Nonetheless, Australia's coral reef communities are threatened by various human activities and climate change. Wisely designed systems of marine reserves are critical to mitigating threats to coral reefs, but existing approaches do not incorporate crucial information about ecological c ....Coral reef connectivity: an empirical and theoretical synthesis. Australia possesses the greatest marine biodiversity of any first world country and this biodiversity is a major contributor to our economic wealth. Nonetheless, Australia's coral reef communities are threatened by various human activities and climate change. Wisely designed systems of marine reserves are critical to mitigating threats to coral reefs, but existing approaches do not incorporate crucial information about ecological connections between reefs. We will use graph theory metrics to identify priority reefs for protection based on empirical genetic and hydrological connectivity information. In addition, we will determine the sensitivity of these priorities to climate change scenarios.Read moreRead less
Network structure, connectivity and wildlife disease. Emerging infectious diseases of wildlife pose threats to human health (75% of human emerging diseases are zoonotic). They also threaten biodiversity and livestock. Changes in connectivity between wildlife individuals and populations are occurring because of human activities, including globalisation, climate change and habitat destruction. Understanding how these changes in connectivity affect wildlife disease dynamics is crucial for the deve ....Network structure, connectivity and wildlife disease. Emerging infectious diseases of wildlife pose threats to human health (75% of human emerging diseases are zoonotic). They also threaten biodiversity and livestock. Changes in connectivity between wildlife individuals and populations are occurring because of human activities, including globalisation, climate change and habitat destruction. Understanding how these changes in connectivity affect wildlife disease dynamics is crucial for the development of better strategies to manage their impacts. The project will also build Australia's wider capacity to manage outbreaks of infectious diseases.Read moreRead less
Theory for global biodiversity conservation. Australia's biological diversity underpins much of our economic wealth - for example the remarkable diversity of coral reefs fuels a multibillion dollar tourism industry. We will devise methods to make better decisions about where to invest conservation dollars amongst the biodiversity "hotspots" of the world and Australia to deliver environmental sustainability. We will solve the problem of how much of any environmental budget should be spent on mo ....Theory for global biodiversity conservation. Australia's biological diversity underpins much of our economic wealth - for example the remarkable diversity of coral reefs fuels a multibillion dollar tourism industry. We will devise methods to make better decisions about where to invest conservation dollars amongst the biodiversity "hotspots" of the world and Australia to deliver environmental sustainability. We will solve the problem of how much of any environmental budget should be spent on monitoring conservation actions to make better and more cost-effective decisions. We will create new theory and freely available tools for building systems of marine reserves that allow for threats like coral bleaching and hurricanes.Read moreRead less
Determining global and regional conservation priorities for biodiversity hotspots. The economic wealth of both Australia and Israel is underpinned by biological diversity - for example the remarkable biological diversity of both countries fuels multimillion-dollar tourism industries. We will devise methods to make better decisions about where to invest conservation dollars amongst the biodiversity 'hotspots' of the Mediterranean ecosystems of the world. We will create and test new theory and to ....Determining global and regional conservation priorities for biodiversity hotspots. The economic wealth of both Australia and Israel is underpinned by biological diversity - for example the remarkable biological diversity of both countries fuels multimillion-dollar tourism industries. We will devise methods to make better decisions about where to invest conservation dollars amongst the biodiversity 'hotspots' of the Mediterranean ecosystems of the world. We will create and test new theory and tools for incorporating into decision making the effect of processes such as climate change and invasion by alien species, which will help reduce the huge detrimental impacts on social, economic, health and human-well being. We will share the results of our work with decision makers and with the public.Read moreRead less
Developing tools for assessing ecological performance of marine protected areas. Marine Protected Areas (MPAs) are rapidly being established around Australia as a device to conserve marine biodiversity. Their ability to sustain animal and plant populations depends critically on the ability of populations to replenish themselves, but we have no ready way of assessing replenishment, relying instead on simple counts of animals and plants within MPAs as a measure of their success. We propose a new ....Developing tools for assessing ecological performance of marine protected areas. Marine Protected Areas (MPAs) are rapidly being established around Australia as a device to conserve marine biodiversity. Their ability to sustain animal and plant populations depends critically on the ability of populations to replenish themselves, but we have no ready way of assessing replenishment, relying instead on simple counts of animals and plants within MPAs as a measure of their success. We propose a new measure, using relationships between adult stocks and recruitment, as a way of assessing the long-term success of MPAs. We will test this measure using comparisons among marine national parks that were established recently in Victoria.Read moreRead less
Innovative systematic conservation planning for Indigenous Land and Sea Country: Torres Strait as a case study. Australia’s Indigenous communities have responsibilities for managing their Land and Sea Country in partnership with governments. Much of Australia’s globally significant biodiversity occurs in Indigenous country. Effective management requires plans to be developed using both western science and Traditional Knowledge to enable local communities to protect both their culture and biodive ....Innovative systematic conservation planning for Indigenous Land and Sea Country: Torres Strait as a case study. Australia’s Indigenous communities have responsibilities for managing their Land and Sea Country in partnership with governments. Much of Australia’s globally significant biodiversity occurs in Indigenous country. Effective management requires plans to be developed using both western science and Traditional Knowledge to enable local communities to protect both their culture and biodiversity. This project will develop innovative scientific tools to assist Indigenous communities and governments to design and implement systematic conservation planning initiatives ‘on country’, using Torres Strait as a case study. The tools that are developed will have general relevance to Australian Indigenous communities and developing countries. Read moreRead less
Integrated, interactive and systematic Marine Protected Area design for sustainability of South Australian marine environments: A GIS-based, spatial optimisation approach. This project aims to enhance MPA design in SA by integrating systematic conservation plannning (SCP), spatial optimisation and Geographic Information Systems (GIS). New, integrated Integer Programming (IP) models will be built based on established SCP principles and nationally agreed marine conservation criteria. The IP models ....Integrated, interactive and systematic Marine Protected Area design for sustainability of South Australian marine environments: A GIS-based, spatial optimisation approach. This project aims to enhance MPA design in SA by integrating systematic conservation plannning (SCP), spatial optimisation and Geographic Information Systems (GIS). New, integrated Integer Programming (IP) models will be built based on established SCP principles and nationally agreed marine conservation criteria. The IP models will be tightly coupled with the GIS to create an interactive Spatial Decision Support Tool (SDSS) for systematic MPA design - the first of its kind. The SDSS will enable real-time, systematic MPA design and will provide flexible design options for a comprehensive, adequate, representative and efficient MPA system for SA.Read moreRead less
Conservation planning: incorporating patch dynamics and climate change to achieve better outcomes. This research will make significant contributions to planning for An Environmentally Sustainable Australia. Key outcomes will include guidelines for including, for the first time, the patch dynamics of coral bleaching and pelagic productivity in conservation planning. By using an Australian icon, the Great Barrier Reef, as the case study for this research, the findings will be directly applicable a ....Conservation planning: incorporating patch dynamics and climate change to achieve better outcomes. This research will make significant contributions to planning for An Environmentally Sustainable Australia. Key outcomes will include guidelines for including, for the first time, the patch dynamics of coral bleaching and pelagic productivity in conservation planning. By using an Australian icon, the Great Barrier Reef, as the case study for this research, the findings will be directly applicable and implementable. Furthermore, this study will result in an understanding of the potential effect of climate change on patch dynamics, and will provide guidelines and theory for planning for such changes. This research will enable Australia to effectively protect its biodiversity and to relate this knowledge to its neighbours.Read moreRead less
Connecting ecological processes controlling variation across spatial scales. Large variability in numbers and types of animals from place to place and time to time characterizes many ecological systems, particularly on the rocky shores along our coasts. It confuses interpretation and hampers predictions about conservation, impacts and climatic change. This programme is a systematic experimental analysis of the major causes of variance (availability of suitable habitat and food, influences of w ....Connecting ecological processes controlling variation across spatial scales. Large variability in numbers and types of animals from place to place and time to time characterizes many ecological systems, particularly on the rocky shores along our coasts. It confuses interpretation and hampers predictions about conservation, impacts and climatic change. This programme is a systematic experimental analysis of the major causes of variance (availability of suitable habitat and food, influences of weather) on the animals and indirectly on their food. The research will unravel the interacting influences that operate over several spatial scales to cause variability in local diversity. This will radically increase our capacity to sustain our coastal fauna.Read moreRead less