Microstructural Analysis and Modelling of Copper Ore Agglomerates for Heap Leaching. The efficient extraction of valuable metals from mined ore can be considered as a problem of global concern as the world's reserves of such metals quickly diminish. For low grade copper ore, heap leaching has long been recognized as the most efficient mineral recovery procedure. This project aims to apply X-ray microtomography and micromechanical modelling to quantify the critical leaching properties of ore aggl ....Microstructural Analysis and Modelling of Copper Ore Agglomerates for Heap Leaching. The efficient extraction of valuable metals from mined ore can be considered as a problem of global concern as the world's reserves of such metals quickly diminish. For low grade copper ore, heap leaching has long been recognized as the most efficient mineral recovery procedure. This project aims to apply X-ray microtomography and micromechanical modelling to quantify the critical leaching properties of ore agglomerates and to formulate optimal heap leaching strategies. This will allow for better utilization of the Australia's low grade ore reserves. The procedures and methodologies to be developed will be applicable to other types of ore including gold, uranium and nickel.Read moreRead less
A computational approach to fracture of quasi-brittle materials across the scales. The mining industry is a significant contributor to the economy of Australia. Since only a small part of the input energy in mining is useful, improving the energy efficiency through simulation-based optimisation of rock fracturing processes will have a huge impact on reducing the costs of mining operations. Besides, the numerical prediction of rock mass failure in mining, and collapse of concrete structures under ....A computational approach to fracture of quasi-brittle materials across the scales. The mining industry is a significant contributor to the economy of Australia. Since only a small part of the input energy in mining is useful, improving the energy efficiency through simulation-based optimisation of rock fracturing processes will have a huge impact on reducing the costs of mining operations. Besides, the numerical prediction of rock mass failure in mining, and collapse of concrete structures under extreme conditions in civil engineering and defence will also benefit from the project. This will improve Australia's capability to deal with catastrophic events. Through advances in numerical simulation of fracture of geomaterials, the project will also enhance Australian research in computational failure mechanics.Read moreRead less