Fingerprints of global climate change and forest management on rhizosphere carbon and nutrient cycling. Using a series of innovative techniques, this project seeks to capture the excellent, exciting opportunities for studying impacts of global climate change (GCC) and forest management on plant-soil-microbe interactions in rhizosphere carbon and nutrient cycling, with two of the world's best GCC forest experiments in Sweden and USA and three long-term forest management experiments in Australia. ....Fingerprints of global climate change and forest management on rhizosphere carbon and nutrient cycling. Using a series of innovative techniques, this project seeks to capture the excellent, exciting opportunities for studying impacts of global climate change (GCC) and forest management on plant-soil-microbe interactions in rhizosphere carbon and nutrient cycling, with two of the world's best GCC forest experiments in Sweden and USA and three long-term forest management experiments in Australia. The successful conduct of this multidisciplinary collaborative research will result in: improved understanding and management of forest ecosystems in response to GCC and effective biodiversity conservation in managed forests; and enhanced international reputation and expertise of the Australian scientists in the relevant research fields.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100066
Funder
Australian Research Council
Funding Amount
$260,000.00
Summary
Enhanced modelling capacity for the Industrial Ecology Virtual Laboratory. Enhanced modelling capacity for the Industrial Ecology Virtual Laboratory:
This project aims to enable Australian research leaders working on the integrated sustainability assessment of policies, products and projects to collaborate in the Industrial Ecology Virtual Laboratory (IELab). It seeks to develop and implement an enhanced modelling capability and suite of online analytical tools to support sustainability scienti ....Enhanced modelling capacity for the Industrial Ecology Virtual Laboratory. Enhanced modelling capacity for the Industrial Ecology Virtual Laboratory:
This project aims to enable Australian research leaders working on the integrated sustainability assessment of policies, products and projects to collaborate in the Industrial Ecology Virtual Laboratory (IELab). It seeks to develop and implement an enhanced modelling capability and suite of online analytical tools to support sustainability scientists and analysts from Australia and abroad conducting research projects of national and international significance. In particular, the project would provide policy-makers, investors and communities with detailed and tailored information to help make better decisions about a sustainable future. By upgrading IELab hardware and analytical and modelling software, the project would be versatile and flexible and remain up to date.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101322
Funder
Australian Research Council
Funding Amount
$371,500.00
Summary
Mapping the water-energy nexus: new knowledge for resources security. This project plans to systematically evaluate energy impacts of urban water security across three interconnected systems: the direct consequences of water supply; the indirect influence of water use in industry and homes; and the remote implications of water security on supply chains. The project intends to use a new, high-resolution, open-access, multi-regional, input-output model of the Australian economy and its resources u ....Mapping the water-energy nexus: new knowledge for resources security. This project plans to systematically evaluate energy impacts of urban water security across three interconnected systems: the direct consequences of water supply; the indirect influence of water use in industry and homes; and the remote implications of water security on supply chains. The project intends to use a new, high-resolution, open-access, multi-regional, input-output model of the Australian economy and its resources use: the Industrial Ecology Virtual Laboratory. It expects to help address escalating energy demands and costs for urban water by identifying alternative and optimal pathways for addressing the energy impacts of water supply.Read moreRead less
Assimilating development objectives in conservation planning. This project will extend the theory and practice of decision science to explore the question of how the apparently divergent objectives of biodiversity conservation and economic development can be balanced. The human modification of natural landscapes is causing species loss to accelerate. Yet land use and infrastructure developments are often necessary to support economic growth. The project plans to develop new methods to map past a ....Assimilating development objectives in conservation planning. This project will extend the theory and practice of decision science to explore the question of how the apparently divergent objectives of biodiversity conservation and economic development can be balanced. The human modification of natural landscapes is causing species loss to accelerate. Yet land use and infrastructure developments are often necessary to support economic growth. The project plans to develop new methods to map past and project future development scenarios for the lower Mekong region in south-east Asia, a globally significant region undergoing rapid economic development. Novel problem formulations would be used to balance biodiversity conservation with development objectives.Read moreRead less
A screening human health risk assessment for developing coal seam gas water resources in Queensland, Australia. Due to its rich coal seam deposits, Queensland is projected to become Australia's leading coal seam gas (CSG) producer, contributing significantly to the State's economy and national "clean" energy targets. Over a 30 year period, it is estimated that Queensland's CSG industry could also create by-product water of sufficient volume to beneficially augment the State's future water supply ....A screening human health risk assessment for developing coal seam gas water resources in Queensland, Australia. Due to its rich coal seam deposits, Queensland is projected to become Australia's leading coal seam gas (CSG) producer, contributing significantly to the State's economy and national "clean" energy targets. Over a 30 year period, it is estimated that Queensland's CSG industry could also create by-product water of sufficient volume to beneficially augment the State's future water supply demands. The proposed screening Health Risk Assessment will evaluate the relative risks associated with human exposure to raw and treated CSG by-product water contaminants, informing public debate on this matter, and guide policy development within the complex multi-sector regulatory framework in place for CSG water resource development in Queensland.Read moreRead less