Integrating economics and science for land, water and biodiversity policy. Australian government programs for land and water conservation involve expenditure of billions of dollars, combined with much larger contributions from program participants. However, various problems with these programs have been identified. This research will assist program investors to better target funding, to employ more appropriate policy mechanisms, and to operate in a cost-effective way, achieving the most highly v ....Integrating economics and science for land, water and biodiversity policy. Australian government programs for land and water conservation involve expenditure of billions of dollars, combined with much larger contributions from program participants. However, various problems with these programs have been identified. This research will assist program investors to better target funding, to employ more appropriate policy mechanisms, and to operate in a cost-effective way, achieving the most highly valued environmental outcomes that can be achieved with the available budget. The project will develop improved theories, frameworks and economic models, integrating information from physical, biological and social sciences, and decision tools for use by environmental decision makers.Read moreRead less
Special Research Initiatives - Grant ID: SR0354677
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Sustainable terrestrial and riverine systems through integrated assessment and modelling. Australia must take the lead internationally in sustainability assessment and management; it hosts both the problems and expertise, and is proactive in integrating research and management. This Initiative unites, for the first time, leading researchers from all relevant disciplines to advance our knowledge for achieving sustainable terrestrial and riverine systems (STARS). The intended network can produce a ....Sustainable terrestrial and riverine systems through integrated assessment and modelling. Australia must take the lead internationally in sustainability assessment and management; it hosts both the problems and expertise, and is proactive in integrating research and management. This Initiative unites, for the first time, leading researchers from all relevant disciplines to advance our knowledge for achieving sustainable terrestrial and riverine systems (STARS). The intended network can produce assessments, strategies and policy directions that are objective, adaptive and inclusive. It can evaluate trade-offs between sustainability strategies, integrating research and outcomes, making them accessible to managers. It will build a coordinated research capability that directly supports Australia's goal of ecologically sustainable development. Read moreRead less
Dynamics of woody vegetation and water in the central Pilbara - understanding and managing for environmental change. The development and application of technologies and knowledge for enhancing sustainable management of semi-arid environments are of high priority and significant economic, social and environmental benefit. The value of iron ore exports from the Pilbara is expected to grow by nearly 30% in the next year, while the projected production of iron ore over the next 4 years is expected t ....Dynamics of woody vegetation and water in the central Pilbara - understanding and managing for environmental change. The development and application of technologies and knowledge for enhancing sustainable management of semi-arid environments are of high priority and significant economic, social and environmental benefit. The value of iron ore exports from the Pilbara is expected to grow by nearly 30% in the next year, while the projected production of iron ore over the next 4 years is expected to be valued in excess of 60 billion dollars. However, continued and rapid expansion in the development of these resources is contingent on environmental oversight and adoption of an adaptive management approach. This research will thus make a major contribution to understanding the Pilbara ecosystems that provide tremendous economic wealth for all Australians.Read moreRead less
Impact of increased sediment and nutrient discharges on the long-term sustainability of the Great Barrier Reef. The Great Barrier Reef, one of Australia's greatest natural assets, is under increasing threat from extreme climatic events caused by global warming and from land-based pollution. This research will identify the main sources of sediment and nutrient pollution caused by river runoff and by how much this has increased above 'natural levels'. We will discover how the very sensitive offsho ....Impact of increased sediment and nutrient discharges on the long-term sustainability of the Great Barrier Reef. The Great Barrier Reef, one of Australia's greatest natural assets, is under increasing threat from extreme climatic events caused by global warming and from land-based pollution. This research will identify the main sources of sediment and nutrient pollution caused by river runoff and by how much this has increased above 'natural levels'. We will discover how the very sensitive offshore coral reefs have responded to increased pollution and whether this is the cause of the very devastating crown-of-thorn-starfish infestations. Understanding the long-term effects of land-based pollution on the ecology of coral reefs in the GBR will thus provide a scientific basis to help ensure that it has a sustainable future.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170101524
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Past and future dynamics in coastal ecosystems. This project aims to understand how humans and nature affect coastal ecosystems. Globally, billions of dollars are spent on understanding ecosystem services and responses to human and natural pressures, but contemporary datasets’ short time-span makes them inadequate, since ecosystems change at multiple spatial and temporal scales. This project will use seagrass archives to reconstruct the history of coastal ecosystems over millennia, identifying b ....Past and future dynamics in coastal ecosystems. This project aims to understand how humans and nature affect coastal ecosystems. Globally, billions of dollars are spent on understanding ecosystem services and responses to human and natural pressures, but contemporary datasets’ short time-span makes them inadequate, since ecosystems change at multiple spatial and temporal scales. This project will use seagrass archives to reconstruct the history of coastal ecosystems over millennia, identifying baseline conditions, the time-course of ecological change, cycles and thresholds of ecosystem dynamics driven by human and natural forces, and determining their role as biogeochemical sinks. Intended outcomes are to manage ecological change and remove constraints on sustainable coastal development.Read moreRead less
Understanding and predicting sediment distribution and net transport in estuaries and coastal oceans with an emphasis on muddy bottom layers. This project will design and implement a field campaign to observe fluid mud layers in the muddy harbours and develop predictive models to investigate these layers. This research will give new direction to port management by developing adaptive tools to solve water quality and siltation problems in muddy ports and harbours in Australia.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775642
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
Stable isotope facility for biological, ecological, and geological applications - West Australian Biogeochemistry Centre. Stable isotope science underpins many disciplines of research, from forensic identification of sources of counterfeit money through to understanding the formation of gold and other mineral deposits. Stable isotope science also provides insights that will improve management of water and land resources, including the impacts of utilisation of groundwater, reducing gaseous emiss ....Stable isotope facility for biological, ecological, and geological applications - West Australian Biogeochemistry Centre. Stable isotope science underpins many disciplines of research, from forensic identification of sources of counterfeit money through to understanding the formation of gold and other mineral deposits. Stable isotope science also provides insights that will improve management of water and land resources, including the impacts of utilisation of groundwater, reducing gaseous emissions from land-use change and knowledge of food webs in marine systems. While a handful of laboratories utilise IRMS around Australia, equipment is fully utilised, outdated and limiting progress. A new IRMS will transform capabilities in WA and enhance projects in terrestrial and marine ecology, ecosystem science and geochemistry of mineral deposits. Read moreRead less
Mitigation of Impacts on Groundwater Dependent Vegetation Through Adaptive Abstraction Regimes. Apart from loss of habitat, biodiversity, ecological function and aesthetics, tree decline and death is a financial burden to land managers. Lost groundwater production from existing borefield infrastructure due to environmental risk also represents a significant economic loss to industry. By adapting borefield operation strategies to be more sympathetic to environmental demands for groundwater, susta ....Mitigation of Impacts on Groundwater Dependent Vegetation Through Adaptive Abstraction Regimes. Apart from loss of habitat, biodiversity, ecological function and aesthetics, tree decline and death is a financial burden to land managers. Lost groundwater production from existing borefield infrastructure due to environmental risk also represents a significant economic loss to industry. By adapting borefield operation strategies to be more sympathetic to environmental demands for groundwater, sustainable use of the resource can be maximized under otherwise 'high-risk' scenarios. This project will result in environmental benefits such as reduced impacts of borefields and economic benefits such as recovery of lost production from 'high-risk' borefields, increased viability of planned schemes and reduced customer cost of water services.Read moreRead less
Ecological sustainability and changing land use in the Pilbara. Land use change is frequently associated with large changes in key elements of 'sustainability? ? biodiversity, productivity, and water and nutrient cycles. However, in the Pilbara, fires and flooding rains are so frequent that detecting consequences of land use change is frequently confounded by other ?disturbances?. We aim, through controlled field experiments, to disentangle effects of land use change (e.g. de-stocking of range ....Ecological sustainability and changing land use in the Pilbara. Land use change is frequently associated with large changes in key elements of 'sustainability? ? biodiversity, productivity, and water and nutrient cycles. However, in the Pilbara, fires and flooding rains are so frequent that detecting consequences of land use change is frequently confounded by other ?disturbances?. We aim, through controlled field experiments, to disentangle effects of land use change (e.g. de-stocking of rangelands, altered water availability through mining activity or infrastructure) from those of natural disturbance and variability (both spatially and temporally). This research will improve understanding of key areas in resilience of rangelands and of major processes that are critical for sustainable management.Read moreRead less
Management of fire-prone shrublands in Western Australia: testing the effects of frequent fire. Understanding the impacts of different fire regimes (frequency, intensity, patchiness, size of fires) on high diversity shrublands will help CALM (the land managers) develop fire management prescriptions that ensure the conservation of rare and threatened flora, and maintain biodiversity. The research will identify relationships between weather, fuel and fire behaviour that is currently lacking for s ....Management of fire-prone shrublands in Western Australia: testing the effects of frequent fire. Understanding the impacts of different fire regimes (frequency, intensity, patchiness, size of fires) on high diversity shrublands will help CALM (the land managers) develop fire management prescriptions that ensure the conservation of rare and threatened flora, and maintain biodiversity. The research will identify relationships between weather, fuel and fire behaviour that is currently lacking for shrubland vegetation types. It offers advances in our understanding of ecosystem structure and function, with applied value in fire management for conservation and asset protection. The project contributes to development of ecological theory, and provides a scientific basis for improved management of Australia's unique natural heritage.Read moreRead less