Developing indicator minerals to geochemically fingerprint mineralized Fe oxide Cu-Au systems: a pilot study around the Ernest Henry Cu-Au mine. Fe oxide Cu-Au deposits represent some of the largest accumulations of economically extractable metal in the earth's crust. However, exploration has been largely ineffective over the last decade, and new methods for their delineation are required to deliver a step-change in the efficiency of exploration programs. The development of a mineral indicator s ....Developing indicator minerals to geochemically fingerprint mineralized Fe oxide Cu-Au systems: a pilot study around the Ernest Henry Cu-Au mine. Fe oxide Cu-Au deposits represent some of the largest accumulations of economically extractable metal in the earth's crust. However, exploration has been largely ineffective over the last decade, and new methods for their delineation are required to deliver a step-change in the efficiency of exploration programs. The development of a mineral indicator scheme to fingerprint potential ?ore-forming? systems using state-of-the-art laser ablation ICP-MS analysis may engender new methods and strategies that lead to exploration success. A baseline study around a known deposit provides the best means to characterize indicators- the Ernest Henry Cu-Au deposit provides the ideal candidate.Read moreRead less
The Influence of particle shape fragmentation and compaction on 3D hopper flow. According to world-leading material scientist Patrick Richard, "Granular materials are ubiquitous in nature and are the second-most manipulated material in industry (the first one is water)". Our research will produce massive three dimensional computer simulations predicting and analysing the influence of particle size and shape on the morphology of industrial and natural granular flows. The results will have directl ....The Influence of particle shape fragmentation and compaction on 3D hopper flow. According to world-leading material scientist Patrick Richard, "Granular materials are ubiquitous in nature and are the second-most manipulated material in industry (the first one is water)". Our research will produce massive three dimensional computer simulations predicting and analysing the influence of particle size and shape on the morphology of industrial and natural granular flows. The results will have directly and immediately relevant applications in a range of Australian industries, including mass mining and minerals processing and will further make a major contribution to understanding and modelling a variety of geo-hazards.
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Fluid mixing in hydrothermal systems. Mixing of fluids within permeable rocks can cause significant chemical changes to the fluids and the rocks, for example it causes metals to be dissolved and transported. Accumulation into mineral deposits requires concentration mechanisms which are uncertain due to difficulty of detecting ancient fluid pathways. We will analyse these ancient fluids using new microanalytical and other combined techniques, thereby testing the role of fluid mixing as a mechanis ....Fluid mixing in hydrothermal systems. Mixing of fluids within permeable rocks can cause significant chemical changes to the fluids and the rocks, for example it causes metals to be dissolved and transported. Accumulation into mineral deposits requires concentration mechanisms which are uncertain due to difficulty of detecting ancient fluid pathways. We will analyse these ancient fluids using new microanalytical and other combined techniques, thereby testing the role of fluid mixing as a mechanism for efficient metal precipitation. The research has significance for exploration and models for mineral deposits, and for characterising other geological fluids, and provides opportunity for technical breakthroughs in microanalysis of fluid inclusions.Read moreRead less
Genetic Algorithms for Open-Cut Mine Scheduling. Open-cut mining depends heavily on long-term scheduling. This project will apply a novel artificial intelligence method, genetic algorithms, to mine scheduling. The aim is to create an improved scheduler as a drop-in replacement for today's methods, which generally assume perfect knowledge of the ore body and future prices and costs. This project will optimize schedules that cope with uncertainties, by searching the possible scenarios to automa ....Genetic Algorithms for Open-Cut Mine Scheduling. Open-cut mining depends heavily on long-term scheduling. This project will apply a novel artificial intelligence method, genetic algorithms, to mine scheduling. The aim is to create an improved scheduler as a drop-in replacement for today's methods, which generally assume perfect knowledge of the ore body and future prices and costs. This project will optimize schedules that cope with uncertainties, by searching the possible scenarios to automatically find the best options for different future contingencies. This will produce flexible schedules, to maintain mine viability and job security despite unpredictable economic fluctuations. About 40% of Australia's exports come from mining, so this proposal will benefit the nation's economy, and make secure mining jobs in rural and regional areas.Read moreRead less
Partial melting in natural metal-silicate and silicate systems: rheological and geochemical implications for the Earth and other planets. Understanding how fluid and melts migrate through the Earth's crust is vital to predicting how important minerals, metals and oil can be concentrated. Understanding fluid-rock systems therefore contribute to an environmentally sustainable Australia (Research Priority 1). Furthering our knowledge of permeable networks through the use of dynamic experiments is a ....Partial melting in natural metal-silicate and silicate systems: rheological and geochemical implications for the Earth and other planets. Understanding how fluid and melts migrate through the Earth's crust is vital to predicting how important minerals, metals and oil can be concentrated. Understanding fluid-rock systems therefore contribute to an environmentally sustainable Australia (Research Priority 1). Furthering our knowledge of permeable networks through the use of dynamic experiments is an innovative way to study their development within naturally evolving crustal systems as they respond to changing physical and chemical conditions. Thus, this proposal is also directly concerned with the continuing aim of building a sustainable Australia through knowledge of deep Earth resources.Read moreRead less