Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346903
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
LC-MS system for Faculty of Sciences, U.N.E. LC-MS is a technique for investigating the composition of complex mixtures and identifying its components. This instrumentation will be utilised at UNE in a diverse range of analytical investigations to further the research aims of scientists in chemistry, biological sciences, archaeology, physics, environmental sciences, marine science as well as biological researchers in specialised units based at UNE. The extraordinarily versatile capacity of this ....LC-MS system for Faculty of Sciences, U.N.E. LC-MS is a technique for investigating the composition of complex mixtures and identifying its components. This instrumentation will be utilised at UNE in a diverse range of analytical investigations to further the research aims of scientists in chemistry, biological sciences, archaeology, physics, environmental sciences, marine science as well as biological researchers in specialised units based at UNE. The extraordinarily versatile capacity of this technique for analysis and identification of organic substances, from small molecules through to large proteins and complex plant and animal metabolites, will provide impetus for existing research and stimulus for new research directions.Read moreRead less
A Cost-Effective System for Monitoring Lightning Strikes Across Australasia. Lightning causes many major fires in Australia, and rural fire managers would benefit from access to lighting data. Lightning data have been prohibitively expensive because acquiring them requires a dense monitoring network. Low Frequency Electromagnetic Research Ltd (LF*EM) has developed an alternative, cost-effective technology for monitoring lightning based on a sparse network of stations monitoring VLF radiation. We ....A Cost-Effective System for Monitoring Lightning Strikes Across Australasia. Lightning causes many major fires in Australia, and rural fire managers would benefit from access to lighting data. Lightning data have been prohibitively expensive because acquiring them requires a dense monitoring network. Low Frequency Electromagnetic Research Ltd (LF*EM) has developed an alternative, cost-effective technology for monitoring lightning based on a sparse network of stations monitoring VLF radiation. We propose to translate LF*EM's basic science results into a product that can deliver lightning data to fire managers and other users across Oceania.Read moreRead less
Trans-dimensional and Approximate Bayesian Computation. Many applied scientists in Australia, particularly those in the biological, medical and environmental sciences are now interested in incorporating Bayesian statistical methodologies into their research.
The development of more generic and efficient Bayesian statistical methods will not only benefit applied statisticians but also the more occasional users of statistics in other disciplinary areas. The success of this project will enhance Au ....Trans-dimensional and Approximate Bayesian Computation. Many applied scientists in Australia, particularly those in the biological, medical and environmental sciences are now interested in incorporating Bayesian statistical methodologies into their research.
The development of more generic and efficient Bayesian statistical methods will not only benefit applied statisticians but also the more occasional users of statistics in other disciplinary areas. The success of this project will enhance Australia's reputation as a strong contributor to the development of Bayesian methodologies. Two PhD students will also be provided training in computational Bayesian statistics.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668526
Funder
Australian Research Council
Funding Amount
$542,000.00
Summary
Biomolecular discovery and analysis facility. This facility will provide Australian researchers with unrivalled access to advanced cell visualisation and analysis tools, which until very recently were only available to the pharmaceutical industry and large US and European institutions. The facility will allow new approaches to identifying novel natural products and understanding cell signalling pathways. Knowledge of these pathways and the identification of molecules that can affect them are key ....Biomolecular discovery and analysis facility. This facility will provide Australian researchers with unrivalled access to advanced cell visualisation and analysis tools, which until very recently were only available to the pharmaceutical industry and large US and European institutions. The facility will allow new approaches to identifying novel natural products and understanding cell signalling pathways. Knowledge of these pathways and the identification of molecules that can affect them are keys to understanding normal cellular physiology and identifying drug-like molecules able to inhibit malfunctioning pathways found in different disease such as cancer. The facility will accellerate drug discovery and basic research in cell biology and underpin National Research Priorities.Read moreRead less
Improving the Credibility of Greenhouse Gas Emissions Disclosures. There is increasing demand for disclosures about greenhouse gas emissions around the world, and a desire to improve their credibility. This study will provide insights into the types of reporting and assurance that can be provided. In addition, it will examine the extent to which users are influenced by the greenhouse gas disclosures and assurance provided. As such, this research will provide an important knowledge base in determ ....Improving the Credibility of Greenhouse Gas Emissions Disclosures. There is increasing demand for disclosures about greenhouse gas emissions around the world, and a desire to improve their credibility. This study will provide insights into the types of reporting and assurance that can be provided. In addition, it will examine the extent to which users are influenced by the greenhouse gas disclosures and assurance provided. As such, this research will provide an important knowledge base in determining the appropriate focus of future reporting and assurance in this area. It is expected that this research will inform the development of an international and Australian assurance standard on greenhouse gas emissions.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
What limits CO2 diffusion inside leaves? Dissecting the diffusion path with Arabidopsis mutants. Human induced increase in atmospheric carbon dioxide is now generally accepted as contributing to global warming. Forecasting our future impact relies on models of terrestrial photosynthesis which use a signature in the atmosphere created by plants when they discriminate against the heavy stable isotope of carbon during photosynthesis. Discrimination between isotopes is affected by carbon dioxide dif ....What limits CO2 diffusion inside leaves? Dissecting the diffusion path with Arabidopsis mutants. Human induced increase in atmospheric carbon dioxide is now generally accepted as contributing to global warming. Forecasting our future impact relies on models of terrestrial photosynthesis which use a signature in the atmosphere created by plants when they discriminate against the heavy stable isotope of carbon during photosynthesis. Discrimination between isotopes is affected by carbon dioxide diffusion within leaves and key steps in this process will be identified through the use of Arabidopsis mutants. Better representation of this process in models will improve estimates of terrestrial photosynthesis and climate change forecastsRead moreRead less
Special Research Initiatives - Grant ID: SR0354620
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Nature, culture and the challenges of environmental sustainability: bridging the science/humanities divide. Australian science currently receives considerable funding for excellent research on environmental issues. There is also significant investment in Humanities and Social Science research on Australian environmental attitudes and practices, and how these change. This proposal seeks to link the largely separate research conversations of the two traditions. We will coordinate interactions betw ....Nature, culture and the challenges of environmental sustainability: bridging the science/humanities divide. Australian science currently receives considerable funding for excellent research on environmental issues. There is also significant investment in Humanities and Social Science research on Australian environmental attitudes and practices, and how these change. This proposal seeks to link the largely separate research conversations of the two traditions. We will coordinate interactions between HSS scholars, often working as individuals, and establish links that bridge the Science/Humanities divide to produce better environmental research outcomes for Australia. The network will add value to existing investments, enhance the international significance of Australian research and foster the next generation of interdisciplinary scholars.Read moreRead less
Development and application of the Uranium-series method for dating ancient rock engravings. Radiocarbon dating has been used to establish the age of relatively recent Australian rock art, but the ages of ancient engravings cannot be measured beyond the limit of this method. Comparative radiocarbon and uranium-series assays will be made on pairs of test samples collected from natural mineral deposits at engraving locations constrained by the ages of lakes, lava flows, sedimentary deposits or ic ....Development and application of the Uranium-series method for dating ancient rock engravings. Radiocarbon dating has been used to establish the age of relatively recent Australian rock art, but the ages of ancient engravings cannot be measured beyond the limit of this method. Comparative radiocarbon and uranium-series assays will be made on pairs of test samples collected from natural mineral deposits at engraving locations constrained by the ages of lakes, lava flows, sedimentary deposits or ice. Using test samples with independent and radiocarbon age controls will give confidence in the uranium dating approach for reliably measuring the ages of similar coatings associated with ancient carvings and exposed rock surfaces throughout the world.Read moreRead less
Minimum sizes and habitat areas for viable populations. This project will address two critical issues in conservation biology: How large do wildlife populations need to be to ensure long-term persistence? How large an area needs to be preserved? At present, no such estimates exist for most species. I will develop realistic population viability analysis (PVA) models (encompassing all threats to persistence) on many bird, mammal, reptile, amphibian, invertebrate and plant species, and estimate the ....Minimum sizes and habitat areas for viable populations. This project will address two critical issues in conservation biology: How large do wildlife populations need to be to ensure long-term persistence? How large an area needs to be preserved? At present, no such estimates exist for most species. I will develop realistic population viability analysis (PVA) models (encompassing all threats to persistence) on many bird, mammal, reptile, amphibian, invertebrate and plant species, and estimate the minimum population sizes and habitat areas required for long-term survival. My prior research has validated the predictive accuracy of PVA. This research will deliver practical guidelines for managing threatened species.Read moreRead less