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Australian Laureate Fellowships - Grant ID: FL180100087
Funder
Australian Research Council
Funding Amount
$2,539,442.00
Summary
Predictive simulation of crystallisation. This project aims to create new methodologies for quantitatively predicting the result of crystallisation processes, which are central to industries from pharmaceutical and food manufacture through to minerals processing. The outcomes will include the commercialisation of new technologies for computer modelling, economic impact in several key industries, and capacity building in analytical skills. Target project applications includes accelerating the dev ....Predictive simulation of crystallisation. This project aims to create new methodologies for quantitatively predicting the result of crystallisation processes, which are central to industries from pharmaceutical and food manufacture through to minerals processing. The outcomes will include the commercialisation of new technologies for computer modelling, economic impact in several key industries, and capacity building in analytical skills. Target project applications includes accelerating the development cycle for pharmaceuticals and reducing scale formation within both oil/gas pipelines and desalination plants.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100007
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
An integrated facility for the advanced characterisation of environmental particles. An integrated facility for the advanced characterisation of environmental particles: This project will result in development of a state-of-the-art facility for comprehensive determination of particle size, concentration and surface properties for a wide range of environmentally occurring particles, in rapid succession. Combining several novel and advanced instruments into an integrated facility will permit in si ....An integrated facility for the advanced characterisation of environmental particles. An integrated facility for the advanced characterisation of environmental particles: This project will result in development of a state-of-the-art facility for comprehensive determination of particle size, concentration and surface properties for a wide range of environmentally occurring particles, in rapid succession. Combining several novel and advanced instruments into an integrated facility will permit in situ and kinetic experiments that are currently unable to be easily undertaken anywhere in Australia. This will enable major progress for internationally significant research activities in areas including sediment geochemistry, contaminant mobility, and biogeochemistry. The project will thus help to address several pressing global environmental issues while adding substantial new capabilities for Australian research.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100417
Funder
Australian Research Council
Funding Amount
$358,508.00
Summary
Unlocking critical metals from Australian sediments and ores. This project aims to explore the recrystallization of nickel-bearing minerals in laterites to extract nickel from stable mineral phases under ambient conditions. Highly-weathered Australian soils contain economic quantities of nickel but technologies to extract this metal are inefficient, leaving this vital resource underdeveloped. This project will use stable isotope tracers and three-dimensional atomic-scale tomography to resolve th ....Unlocking critical metals from Australian sediments and ores. This project aims to explore the recrystallization of nickel-bearing minerals in laterites to extract nickel from stable mineral phases under ambient conditions. Highly-weathered Australian soils contain economic quantities of nickel but technologies to extract this metal are inefficient, leaving this vital resource underdeveloped. This project will use stable isotope tracers and three-dimensional atomic-scale tomography to resolve the recrystallization mechanisms, and determine their role in natural environments and their applicability to natural ores. Expected outcomes include strategies to process nickel-rich laterites, of high interest to industry and society in Australia and abroad.This project will exemplify the need to promote novel solutions to reduce the financial and environmental cost of processing natural resources.Read moreRead less
Understanding mineral reactivity using computer simulations at realistic pH. The results of fundamental environmental and technological processes such as the production of alumina and the management of mine wastes largely depend on careful controlling the conditions at which the chemical reactions occur. Throughout this project, atomistic simulations will be used to unravel the effects of pH on the stability of minerals and to improve our knowledge of the dissolution and re-precipitation mechani ....Understanding mineral reactivity using computer simulations at realistic pH. The results of fundamental environmental and technological processes such as the production of alumina and the management of mine wastes largely depend on careful controlling the conditions at which the chemical reactions occur. Throughout this project, atomistic simulations will be used to unravel the effects of pH on the stability of minerals and to improve our knowledge of the dissolution and re-precipitation mechanisms of these materials. A better understanding of the basic science underpinning minerals’ reactivity will eventually translate into the development of new technologies and contribute to helping Australia’s advancement in developing a sustainable future as well as environment preservation and remediation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100076
Funder
Australian Research Council
Funding Amount
$155,000.00
Summary
The first Australian high pressure Synchrotron facility for geoscience research. In high-pressure mineral physics and chemistry, mineral properties, stress-strain relationships and processes like partial melting are applied to geophysical research about the deep Earth. This project will provide a large volume, high pressure capability at the Australian Synchrotron which will allow these mineral properties to be measured under conditions which simulate the deep earth.
Producing clean energy through geomimetic chemistry. This project aims to provide new chemical pathways able to produce clean energy by following a computational geomimetic approach. It will generate new knowledge in the field of materials science, by characterising the rich mineral chemistry observed on ocean floors and in extra-terrestrial environments that is naturally able to produce fuel through harvesting carbon dioxide. Expected outcomes include a full understanding of chemical reactions ....Producing clean energy through geomimetic chemistry. This project aims to provide new chemical pathways able to produce clean energy by following a computational geomimetic approach. It will generate new knowledge in the field of materials science, by characterising the rich mineral chemistry observed on ocean floors and in extra-terrestrial environments that is naturally able to produce fuel through harvesting carbon dioxide. Expected outcomes include a full understanding of chemical reactions that are at present unexplored at a fundamental level. This will open new perspectives in their potential employment to address the contemporary challenge of producing clean energy and will generate environmental and economic benefit to the Australian and international communities.Read moreRead less
Uncovering molecular pathways to minerals for control of crystallisation. This project aims to increase our knowledge of the processes of mineral formation and crystallisation. Minerals play a vital role in our environment, for example as reservoirs for carbon dioxide, while also substantially contributing to the Australian economy. Conversely, undesirable formation of minerals can be detrimental to industries from the oil/gas sector through to desalination. Despite the benefits that would come ....Uncovering molecular pathways to minerals for control of crystallisation. This project aims to increase our knowledge of the processes of mineral formation and crystallisation. Minerals play a vital role in our environment, for example as reservoirs for carbon dioxide, while also substantially contributing to the Australian economy. Conversely, undesirable formation of minerals can be detrimental to industries from the oil/gas sector through to desalination. Despite the benefits that would come from controlling such crystal growth, progress has been limited by the lack of a complete understanding of how minerals form at the microscopic level. This project aims to combine computer simulation, using the latest petascale resources, with experimental data to yield knowledge that would allow us to manipulate minerals, such as calcium carbonate, with the same control found in nature.Read moreRead less
Using fossil micrometeorites to examine the ancient Earth environment. This project aims to use fossil micrometeorites to provide fundamental new data on changes in the chemistry of the ancient Earth's upper atmosphere before, during and after the Great Oxidation Event, the most significant atmospheric change in Earth’s history. This would provide insights into variations in the extent of interaction between the upper and lower atmosphere across the Great Oxidation Event. The project will also u ....Using fossil micrometeorites to examine the ancient Earth environment. This project aims to use fossil micrometeorites to provide fundamental new data on changes in the chemistry of the ancient Earth's upper atmosphere before, during and after the Great Oxidation Event, the most significant atmospheric change in Earth’s history. This would provide insights into variations in the extent of interaction between the upper and lower atmosphere across the Great Oxidation Event. The project will also use these micrometeorites to investigate how the flux, composition and sources of extra-terrestrial material arriving on Earth changed over time.Read moreRead less
Unravelling vanadium biogeochemistry in modern marine sediments. This project aims to unravel the biogeochemistry of vanadium in modern marine sediments for use as a tracer of ancient oxygen concentrations in the oceans of the early Earth. This project will generate fundamental knowledge on the behaviour of vanadium in modern marine sediments by applying advanced analytical tools for imaging its concentration and chemical form at ultra-high resolution. This information is critical for accurate i ....Unravelling vanadium biogeochemistry in modern marine sediments. This project aims to unravel the biogeochemistry of vanadium in modern marine sediments for use as a tracer of ancient oxygen concentrations in the oceans of the early Earth. This project will generate fundamental knowledge on the behaviour of vanadium in modern marine sediments by applying advanced analytical tools for imaging its concentration and chemical form at ultra-high resolution. This information is critical for accurate interpretation of the geological record to infer the oxygen concentration of the oceans at various points in Earth's history. This interdisciplinary project will facilitate strong collaboration between Australian and Danish researchers in the field of marine geochemistry and paleoceanography.Read moreRead less
The structure and geochemistry of mineral interfaces in Earth's mantle. The interfaces between mineral grains are critical in determining rock properties and behaviour, yet we know little about them. This project uses emerging nano-technologies to establish the structure, chemistry and energy characteristics of interfaces in rocks from Earth’s mantle that control fundamental Earth processes such as plate tectonics and melting. The expected outcomes include a new understanding on one of the funda ....The structure and geochemistry of mineral interfaces in Earth's mantle. The interfaces between mineral grains are critical in determining rock properties and behaviour, yet we know little about them. This project uses emerging nano-technologies to establish the structure, chemistry and energy characteristics of interfaces in rocks from Earth’s mantle that control fundamental Earth processes such as plate tectonics and melting. The expected outcomes include a new understanding on one of the fundamental controls on rock properties and an enhanced ability to predict and model rock behaviour. The project provides research training in innovative research methodologies, will strengthen Australia’s leadership in nano-geoscience and will provide new methodologies for advanced rock characterisation.Read moreRead less