Special Research Initiatives - Grant ID: SR0354804
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
ARC Research Network on Degraded Environment Assessment and Remediation. There are over 80,000 contaminated sites in Australia and >750,000,000 hectares of land impacted by soil acidity, sodicity, heavy-metals, nutrients and agricultural chemicals. The research network advances assessment, management and remediation of degraded environments (land, water, and air) through collaboration of the research programs developing sustainable solutions. The collective focus is minimising disposal and impac ....ARC Research Network on Degraded Environment Assessment and Remediation. There are over 80,000 contaminated sites in Australia and >750,000,000 hectares of land impacted by soil acidity, sodicity, heavy-metals, nutrients and agricultural chemicals. The research network advances assessment, management and remediation of degraded environments (land, water, and air) through collaboration of the research programs developing sustainable solutions. The collective focus is minimising disposal and impacts of contaminated soil and wastes, and land remediation. By facilitating communication, the network enhances national and international research coordination, interaction with regulators, end-users, industry, and other stakeholders, achievement of critical mass for new initiatives, enhances research training and contributes to a critical National Priority.Read moreRead less
Environmental Genomics: Mining, climate change, water, crime and health. The new Environmental Genomics approach will employ high-powered genome sequencing systems to perform some of the first detailed genetic studies of Australian environments. The resulting high-resolution data will comprise a genetic audit, providing essential information for the accurate measurement of climate and environmental change. This method will dramatically improve the speed, and power of environmental impact assessm ....Environmental Genomics: Mining, climate change, water, crime and health. The new Environmental Genomics approach will employ high-powered genome sequencing systems to perform some of the first detailed genetic studies of Australian environments. The resulting high-resolution data will comprise a genetic audit, providing essential information for the accurate measurement of climate and environmental change. This method will dramatically improve the speed, and power of environmental impact assessments, permitting responsible resource development with major benefits to industry and the economy. It will also create new tools to improve water management and quality, biosecurity, forensics/policing and human health, as reflected by the diverse range of industry partners supporting this project.Read moreRead less
Impact of industrially based endocrine disrupting chemicals on aquatic biota. Endocrine disrupting chemicals (EDCs) are a serious threat to aquatic organisms, livestock and humans. EDCs are present in water discharged from sewage treatment plants and in leachate from contaminated land. This project will determine the impact of EDCs from contaminated landfill on aquatic animals. It will also identify the chemicals responsible for biological impact by developing new bio-assays suitable for industr ....Impact of industrially based endocrine disrupting chemicals on aquatic biota. Endocrine disrupting chemicals (EDCs) are a serious threat to aquatic organisms, livestock and humans. EDCs are present in water discharged from sewage treatment plants and in leachate from contaminated land. This project will determine the impact of EDCs from contaminated landfill on aquatic animals. It will also identify the chemicals responsible for biological impact by developing new bio-assays suitable for industrial, scientific and regulatory authority applications. This research has wide-ranging relevance and value to Australian State and Federal regulators and industries because of the ubiquity of sewage treatment plants and contaminated leachate from landfills.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101409
Funder
Australian Research Council
Funding Amount
$432,447.00
Summary
Quantifying trophic niches to measure the resilience of marine predators. This project aims to pair global movement with feeding ecology datasets to characterise relationships between space use and diet breadth, and tests the effects of marine industries on functional roles of marine predators. This expects to generate knowledge about population and individual specalisation using innovative biochemical approaches and shark’s unique dental anatomy. Expected outcomes include a biochemical database ....Quantifying trophic niches to measure the resilience of marine predators. This project aims to pair global movement with feeding ecology datasets to characterise relationships between space use and diet breadth, and tests the effects of marine industries on functional roles of marine predators. This expects to generate knowledge about population and individual specalisation using innovative biochemical approaches and shark’s unique dental anatomy. Expected outcomes include a biochemical database facilitating global collaborations, and a vulnerability scale to rank resilience to impacts based on relative specalisation. This should benefit managers by accounting for previously unknown effects of marine industries on specialists at elevated extinction risk, with limited resilience to local impacts and global change.Read moreRead less
Taking eDNA underground: transforming assessment of subterranean ecosystems. This project aims to improve Environmental Impact Assessment and monitoring of subterranean ecosystems by developing a rigorous, credible and practicable environmental DNA assessment framework. Resource companies in Western Australia are mandated to assess groundwater biodiversity under Environmental Protection legislation. Current surveys are time-consuming (expensive) and biased toward common taxa. For regulators, sta ....Taking eDNA underground: transforming assessment of subterranean ecosystems. This project aims to improve Environmental Impact Assessment and monitoring of subterranean ecosystems by developing a rigorous, credible and practicable environmental DNA assessment framework. Resource companies in Western Australia are mandated to assess groundwater biodiversity under Environmental Protection legislation. Current surveys are time-consuming (expensive) and biased toward common taxa. For regulators, stakeholders and industry involved in this project we will provide real-world information and cost savings through innovation in understanding patterns in species boundaries and detection of subterranean fauna. The outcomes will be directly applicable to monitoring subterranean ecosystems across Australia and internationally.Read moreRead less
The fate and toxicity of nanoparticles in the terrestrial environment. This research aims to provide the knowledge needed to understand the fate and effects of new nanoparticulate metal products in Australian landscapes. The movement and environmental effects of manufactured nanoparticulates are unknown, partly because of the difficulty of measuring and detecting these nano-products in the environment. This project will develop techniques to identify manufactured nanoparticulate metals in soils, ....The fate and toxicity of nanoparticles in the terrestrial environment. This research aims to provide the knowledge needed to understand the fate and effects of new nanoparticulate metal products in Australian landscapes. The movement and environmental effects of manufactured nanoparticulates are unknown, partly because of the difficulty of measuring and detecting these nano-products in the environment. This project will develop techniques to identify manufactured nanoparticulate metals in soils, and to determine the potential adverse effects of these products on plants and soil organisms. This will indicate the need, if any, for controls on the disposal or dispersal of nano-sized metal products in the terrestrial environment.Read moreRead less
Functional characterisation of contaminant-nanoparticle associations. Nanoparticles present in the environment modify the movement and toxicity of contaminants. This project targets key gaps that hinder the ability to predict the fate and behaviour of environmental contaminants; this will lead to the optimisation of legislative framework and the management/remediation of contaminated sites (for example, mine sites, landfills).
Is mass commercialisation of silver-based nanotechnology undermining its biomedical antibacterial potential? Silver nanoparticles have demonstrated broad spectrum antibacterial potential and are increasingly used in biomedical applications to limit infection. They are also found in a growing range of everyday products such as shampoos and socks. This situation is analogous to the previous use of antibiotics for nonmedical purposes and the subsequent spread of antibiotic resistant bacteria. This ....Is mass commercialisation of silver-based nanotechnology undermining its biomedical antibacterial potential? Silver nanoparticles have demonstrated broad spectrum antibacterial potential and are increasingly used in biomedical applications to limit infection. They are also found in a growing range of everyday products such as shampoos and socks. This situation is analogous to the previous use of antibiotics for nonmedical purposes and the subsequent spread of antibiotic resistant bacteria. This project will measure silver resistance selection pressure in key microbial communities. Novel monitoring devices, a multi-technique chemistry approach, and correlative synchrotron spectroscopy and molecular biology techniques will be used to decipher the environmental silver resistome and its likely significance.Read moreRead less
A surface functionality based approach for the risk assessment of manufactured nanomaterials in the environment. Manufactured nanoparticles are increasingly present in the environment yet their risk assessment is fraught with analytical challenges. This project will use customised nanoparticles with unique isotopic signatures and surface properties to circumvent key difficulties and support novel investigations into nanoparticle stability, fate and toxicity.
The role of engineered nanoparticles in the transport of environmental contaminants and the implications for remediation. Engineered nanoparticles are common in the environment due to their widespread industrial use. However, their influence on contaminant mobility is not known. This project will advance our understanding of the interactions of nanoparticles with environmental contaminants and thereby deliver safer and more sustainable remediation technologies.