Discovery Early Career Researcher Award - Grant ID: DE190100614
Funder
Australian Research Council
Funding Amount
$408,000.00
Summary
New classes of aluminium-magnesium-silicon alloys via scandium additions. This project aims to establish the knowledge required to be able to improve Aluminium (Al) alloys using scandium (Sc). The transport sector accounts for 20 per cent of all greenhouse gas emissions globally, and the use of Al to reduce the weight of vehicles offers the potential to significantly reduce these emissions, however the properties of current Al alloys do not meet the necessary requirements. To overcome this chall ....New classes of aluminium-magnesium-silicon alloys via scandium additions. This project aims to establish the knowledge required to be able to improve Aluminium (Al) alloys using scandium (Sc). The transport sector accounts for 20 per cent of all greenhouse gas emissions globally, and the use of Al to reduce the weight of vehicles offers the potential to significantly reduce these emissions, however the properties of current Al alloys do not meet the necessary requirements. To overcome this challenge there is a need for new Al alloys with optimal balance of cost and performance. One opportunity in this area is the use of Sc, however the high Sc price has restricted research thus far. With the recent discovery of rich sources of Sc in Australia, the price of Sc will drop and become a viable solution. This will provide benefits by securing Australia’s position as a leader in the field of advanced Al products for engineering applications.Read moreRead less
Enhanced Fractionation of Mineral Particles According to Density. Aims: -to achieve a significant advance in the hydrodynamic fractionation of particles on the basis of density, and develop an algorithm to deconvolve the fractionation data to produce the underlying density distribution of the particles. Significance: This density distribution, which is used in resource assessment, plant design, and process evaluation in mineral processing, is currently produced using toxic, and environmentally d ....Enhanced Fractionation of Mineral Particles According to Density. Aims: -to achieve a significant advance in the hydrodynamic fractionation of particles on the basis of density, and develop an algorithm to deconvolve the fractionation data to produce the underlying density distribution of the particles. Significance: This density distribution, which is used in resource assessment, plant design, and process evaluation in mineral processing, is currently produced using toxic, and environmentally damaging heavy liquids, despite the emergence of alternative mineral analysers. Expected Outcomes: -a safe, cost effective basis for generating the density distribution. Benefits: -increasing mineral resource recovery through improved access to critical data, while eliminating the need for the toxic heavy liquids.
Read moreRead less
Inorganic membrane percrystallisation in hydrometallurgy. This project aims is to develop the scientific and engineering basis for a new Australian inorganic membrane technology for the crystallisation of metal compounds. Inorganic membrane percrystallisation is a recent breakthrough promising improved productivity, energy savings and the ability to tailor particle properties. This project will develop a mechanistic model encompassing solution transport phenomena, crystal nucleation-growth-agglo ....Inorganic membrane percrystallisation in hydrometallurgy. This project aims is to develop the scientific and engineering basis for a new Australian inorganic membrane technology for the crystallisation of metal compounds. Inorganic membrane percrystallisation is a recent breakthrough promising improved productivity, energy savings and the ability to tailor particle properties. This project will develop a mechanistic model encompassing solution transport phenomena, crystal nucleation-growth-agglomeration and engineering process parameters affecting single and binary salt systems. This model will provide a basis for technology development benefiting Australia, such as the improvement of the production of nickel sulphate for the growing battery materials market.Read moreRead less
ARC Centre of Excellence for Enabling Eco-Efficient Beneficiation of Minerals. The aim of the Centre is to progress scientific knowledge to establish transformational improvement in minerals beneficiation, essential for meeting global demand for metals. The research aims to achieve more selective, faster, and efficient separations, combining major advances in separation technologies with increased functionality of new reagents. The Centre outcomes will also ensure the sustainability of the miner ....ARC Centre of Excellence for Enabling Eco-Efficient Beneficiation of Minerals. The aim of the Centre is to progress scientific knowledge to establish transformational improvement in minerals beneficiation, essential for meeting global demand for metals. The research aims to achieve more selective, faster, and efficient separations, combining major advances in separation technologies with increased functionality of new reagents. The Centre outcomes will also ensure the sustainability of the minerals industry in Australia, through a significant reduction in cost, environmental impact, and through lower energy and water usage. The Centre also seeks to establish a new generation of scientists and research leaders in minerals beneficiation to support the innovation needed into the future by this major Australian industry.Read moreRead less
Predicting the recovery of composite mineral particles in froth flotation. This project aims to provide a new method of predicting the recovery of valuable metals such as copper, gold and lithium from ores using the flotation process. The project will provide new way of modelling the behaviour of individual flotation cells, and banks of cells in series. The project will provide benefits to existing operations such as the minerals and coal industries, which are heavy users of flotation technology ....Predicting the recovery of composite mineral particles in froth flotation. This project aims to provide a new method of predicting the recovery of valuable metals such as copper, gold and lithium from ores using the flotation process. The project will provide new way of modelling the behaviour of individual flotation cells, and banks of cells in series. The project will provide benefits to existing operations such as the minerals and coal industries, which are heavy users of flotation technology. New insights into the behaviour of composite particles will lead to more efficient operations and a new way of scale-up in the design of full-scale plant, which will permit designers to optimise circuits and minimise capital and operating costs.Read moreRead less
Mitigating the negative effects of process water on recovering gold. Low quality water has been used in the minerals industry to save fresh water but shows harmful effects on gold extraction. This project aims to understand the interactions of organic and inorganic components, existing in process water, with gold and determine problematic components that inhibit gold extraction. Expected outcomes will be developed bio-sorbents, based on agriculture waste, that can remove the problematic componen ....Mitigating the negative effects of process water on recovering gold. Low quality water has been used in the minerals industry to save fresh water but shows harmful effects on gold extraction. This project aims to understand the interactions of organic and inorganic components, existing in process water, with gold and determine problematic components that inhibit gold extraction. Expected outcomes will be developed bio-sorbents, based on agriculture waste, that can remove the problematic components in process water efficiently and economically. This will provide major benefits for the minerals industry by providing options to respond and adapt to the impacts of water quality change, leading to increases in yield, revenue and growth of the precious metal sector whilst cutting poisonous chemical consumptions.Read moreRead less
Improving the processing of low-grade copper ores . The project aims to investigate the electrochemical interaction occurring during the grinding of low-grade copper ores and understand how the interaction affects the recovery of copper minerals and rejection of waste minerals in the subsequent separation process. This project expects to generate new knowledge in the area of minerals processing and materials engineering using interdisciplinary approaches. Expected outcomes of this project includ ....Improving the processing of low-grade copper ores . The project aims to investigate the electrochemical interaction occurring during the grinding of low-grade copper ores and understand how the interaction affects the recovery of copper minerals and rejection of waste minerals in the subsequent separation process. This project expects to generate new knowledge in the area of minerals processing and materials engineering using interdisciplinary approaches. Expected outcomes of this project include cost-effective new steel products used for grinding copper ores and new chemical solutions to selectively reject waste minerals during mineral separation. This should significantly reduce the operating costs in copper processing plants and increase the copper production from low-grade copper ores.Read moreRead less
Depressing pyrrhotite in copper and gold flotation. The mining industry is processing low-grade ores associated with high amounts of waste minerals. Extracting metals from low-grade ores is very difficult with technical challenges in rejecting waste minerals. This project aims to understand the surface properties and the behaviour of a major waste mineral which is becoming increasingly problematic during the processing of copper and gold ores. New chemistry and chemical reagents will be develope ....Depressing pyrrhotite in copper and gold flotation. The mining industry is processing low-grade ores associated with high amounts of waste minerals. Extracting metals from low-grade ores is very difficult with technical challenges in rejecting waste minerals. This project aims to understand the surface properties and the behaviour of a major waste mineral which is becoming increasingly problematic during the processing of copper and gold ores. New chemistry and chemical reagents will be developed to efficiently and economically reject the waste mineral by manipulating the reactions that take place on its surface. This project expects to have immediate economic and environmental impacts through increasing metal production, cutting greenhouse gas emissions and applying new green reagents.Read moreRead less