Rehabilitation strategies for metalliferous mine wastes using native metallophytes from Pb-Zn-Ag gossans, northwest Queensland. The global area covered with mine waste is in the order of 100 million hectares containing several 100,000 million tonnes of mine wastes. The long-term sustainable rehabilitation of metal mine sites is inhibited by our lack of knowledge of metal resistance and uptake by Australian native plants. This project will evaluate metallophytes naturally growing on metal-rich so ....Rehabilitation strategies for metalliferous mine wastes using native metallophytes from Pb-Zn-Ag gossans, northwest Queensland. The global area covered with mine waste is in the order of 100 million hectares containing several 100,000 million tonnes of mine wastes. The long-term sustainable rehabilitation of metal mine sites is inhibited by our lack of knowledge of metal resistance and uptake by Australian native plants. This project will evaluate metallophytes naturally growing on metal-rich soils, northwest Queensland, for their capabilities and revegetation potential when grown in mine wastes of the Cannington Ag-Pb-Zn mine. Outcomes will include practical, innovative methods of mine site rehabilitation that are low-cost and environmentally-friendly.Read moreRead less
Antimony geochemistry and Earth's dynamic near-surface iron cycle. This project aims to advance our fundamental understanding on the geochemistry of antimony – a critical mineral resource and environmental pollutant of growing concern. This will be achieved by pioneering an innovative combination of advanced synchrotron-based tools and sophisticated isotopic approaches to unravel important interactions between antimony geochemistry and the iron cycle in soils, sediments and aquatic systems. The ....Antimony geochemistry and Earth's dynamic near-surface iron cycle. This project aims to advance our fundamental understanding on the geochemistry of antimony – a critical mineral resource and environmental pollutant of growing concern. This will be achieved by pioneering an innovative combination of advanced synchrotron-based tools and sophisticated isotopic approaches to unravel important interactions between antimony geochemistry and the iron cycle in soils, sediments and aquatic systems. The expected outcomes will provide novel insights into refined strategies to manipulate coupling between antimony mobility and iron cycling for improved rehabilitation of degraded landscapes, safe disposal of hazardous wastes and sustainable exploitation of Australia’s valuable antimony reserves.Read moreRead less
Polymetallic phytoextraction applied to mine waste. Phytoextraction involves the use of hyperaccumulator plants to grow and concentrate a metal. Subsequently, the crop is harvested and the metal extracted. The aim of this research is to investigate the uptake and chemically induced uptake of heavy metals (Ni, Co, Au, Ag, Cu, Pb, Zn, Pt, Pd, Cr) by plants grown on mine tailings and mine waste materials. Outcomes will include practical methods of metal extraction that are cheap to employ where met ....Polymetallic phytoextraction applied to mine waste. Phytoextraction involves the use of hyperaccumulator plants to grow and concentrate a metal. Subsequently, the crop is harvested and the metal extracted. The aim of this research is to investigate the uptake and chemically induced uptake of heavy metals (Ni, Co, Au, Ag, Cu, Pb, Zn, Pt, Pd, Cr) by plants grown on mine tailings and mine waste materials. Outcomes will include practical methods of metal extraction that are cheap to employ where metal concentrations are subeconomic and of potential environmental impact during mining and after mine closure.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989680
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Interuniversity Elemental and Structural Analytical Facility. The items in this proposal will form the first stage of a larger facility for Elemental and Structural analytical programs in materials engineering and the natural sciences. The vision is to create an analytical facility which will have at its core and at the outset true collaboration leading to great national benefit. The equipment will be available via on-line access management allowing equitable and transparent access for users fro ....Interuniversity Elemental and Structural Analytical Facility. The items in this proposal will form the first stage of a larger facility for Elemental and Structural analytical programs in materials engineering and the natural sciences. The vision is to create an analytical facility which will have at its core and at the outset true collaboration leading to great national benefit. The equipment will be available via on-line access management allowing equitable and transparent access for users from multiple institutions. The resulting facility will complement existing microstructural capabilities and networks and will be open for all researchers and collaborators to use, further enhancing the national benefit.Read moreRead less
Geochemical, physical and microbiological controls on zinc mobility and implications for bioremediation strategies in Western Tasmanian acid mine drainage. We propose to study heavy metal pollution (e.g., zinc, arsenic, iron, tin) and biogeochemical processes operating in acid mine drainage at the abandoned Mt Bischoff tin mine in Western Tasmania. The drainage waters at this site have pH values as low as 2, but contain an extensive and thriving natural biological community. We will evaluate w ....Geochemical, physical and microbiological controls on zinc mobility and implications for bioremediation strategies in Western Tasmanian acid mine drainage. We propose to study heavy metal pollution (e.g., zinc, arsenic, iron, tin) and biogeochemical processes operating in acid mine drainage at the abandoned Mt Bischoff tin mine in Western Tasmania. The drainage waters at this site have pH values as low as 2, but contain an extensive and thriving natural biological community. We will evaluate whether the natural biogeochemical processes operating at Mt Bischoff have the potential to remediate mine waters under the full gamut of climatic conditions, so as to evaluate whether the biota could be exported to other mine sites to help in ameliorating acid drainage problems.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100007
Funder
Australian Research Council
Funding Amount
$170,000.00
Summary
Metal speciation for complex studies in changing environments. Metal speciation for complex studies in changing environments: The Inductively Coupled Plasma Mass Spectrometer with a High Performance Liquid Chromatography front end (HPLC-ICP-MS) for metal speciation studies is a highly valuable extension of existing cutting edge infrastructure for geochemical research. Existing invertebrate culturing capacity will also enable unique opportunities for experimental studies driven by understanding m ....Metal speciation for complex studies in changing environments. Metal speciation for complex studies in changing environments: The Inductively Coupled Plasma Mass Spectrometer with a High Performance Liquid Chromatography front end (HPLC-ICP-MS) for metal speciation studies is a highly valuable extension of existing cutting edge infrastructure for geochemical research. Existing invertebrate culturing capacity will also enable unique opportunities for experimental studies driven by understanding metal speciation and uptake by organisms. This facility will be housed within a highly productive research environment providing new and novel capabilities to study abiotic and biotic interactions in changing environments.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100145
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
Three-dimensional analysis of important organic components in energy, environmental and earth systems. Australia’s ecosystems and water resources are sensitive to climate change and anthropogenic activities. A third degree of separation provided by this technique will improve our abilities to monitor the role of organic matter in modern systems. The characterisation of organics of petroleum mineral systems will sustain Australia's energy demand.
Unraveling hexavalent chromium formation and fate in fire-impacted soil. Hexavalent chromium is a cancer-causing toxin. It can form via heating of natural (unpolluted) soil during bushfires. However, little is known of the processes and factors which govern its formation and behavior in fire-impacted soil. Using a combination of field-based investigations, innovative experiments and cutting edge analytical approaches, this project aims to systematically explore hexavalent chromium formation vi ....Unraveling hexavalent chromium formation and fate in fire-impacted soil. Hexavalent chromium is a cancer-causing toxin. It can form via heating of natural (unpolluted) soil during bushfires. However, little is known of the processes and factors which govern its formation and behavior in fire-impacted soil. Using a combination of field-based investigations, innovative experiments and cutting edge analytical approaches, this project aims to systematically explore hexavalent chromium formation via fire-induced heating of soil and to examine its post-fire fate in soil systems. The results will transform our understanding of the chromium cycle at the Earth’s surface, and will facilitate accurate assessment and mitigation of the risks posed by hexavalent chromium formation in fire-impacted soil.Read moreRead less
A new paradigm for the accumulation and persistence of metastable iron sulphides in sulphidic soils. Metastable iron sulphide minerals have a critical role in controlling surface- and ground-water quality. This project will transform our understanding of the environmental geochemistry of metastable iron sulphides in sulphidic soils. This will greatly enhance our ability to predict and manage water quality in a wide range of important aquatic systems.
Unraveling the nitrogen cycle in a periodically anoxic estuary. Climate change is likely to lead to reduced river inflows to estuaries which can lead to oxygen depletion and major changes in nutrient cycling. This project will help inform the public and policy makers about the role of environmental flows in maintaining estuarine function, and thus guide future decisions on environmental flow requirements in the Yarra River Estuary. The benefits of this understanding will also flow on to improv ....Unraveling the nitrogen cycle in a periodically anoxic estuary. Climate change is likely to lead to reduced river inflows to estuaries which can lead to oxygen depletion and major changes in nutrient cycling. This project will help inform the public and policy makers about the role of environmental flows in maintaining estuarine function, and thus guide future decisions on environmental flow requirements in the Yarra River Estuary. The benefits of this understanding will also flow on to improved understanding and management of nitrogen loads to Port Phillip Bay. This project will form a close collaborative partnership between Monash University, Melbourne Water and the EPA. This collaboration will ensure the integration of cutting edge science with innovative management regimes Read moreRead less