SYNCHROTRON MICROPROBE METALLURGICAL CASE STUDIES. The micro-focus capabilities of synchrotron techniques (XRF, XRD, XAS) will enable the high resolution spatial correlations required to advance the understanding of the three systems to be studied:
- Activation for flotation of sphalerite with varying iron contents;
- Arsenic leaching as a function of local structure, phase and mineral assemblage;
- Optimisation of ferrous alloy microstructure on cryogenic treatment.
These case studies have ....SYNCHROTRON MICROPROBE METALLURGICAL CASE STUDIES. The micro-focus capabilities of synchrotron techniques (XRF, XRD, XAS) will enable the high resolution spatial correlations required to advance the understanding of the three systems to be studied:
- Activation for flotation of sphalerite with varying iron contents;
- Arsenic leaching as a function of local structure, phase and mineral assemblage;
- Optimisation of ferrous alloy microstructure on cryogenic treatment.
These case studies have been chosen to specifically target the minerals processing and manufacturing industrial sectors and will be used to increase industrial awareness of the potentials of synchrotron techniques prior to the commissioning of the Australian Synchrotron in 2007.
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A study of high temperature transformation of oil shale - In-situ mineral reactions and structure analysis. In the current energy market, non-traditional fuels like oil shale are becoming more economically important. Australia has >33 billion tonnes of oil shales resources with potential for >1800 million tonnes of recoverable oil. This potential multi-billion dollar industry depends upon development of an efficient technology leading to economical oil production and much cleaner organic liquid ....A study of high temperature transformation of oil shale - In-situ mineral reactions and structure analysis. In the current energy market, non-traditional fuels like oil shale are becoming more economically important. Australia has >33 billion tonnes of oil shales resources with potential for >1800 million tonnes of recoverable oil. This potential multi-billion dollar industry depends upon development of an efficient technology leading to economical oil production and much cleaner organic liquid fuels. Retorting and combustion, which are core parts of oil shale conversion technology, would benefit from improved process conditions. This research proposal intends to investigate the in-situ complex oil shale thermal conversion reactions that occur during the retorting and combustion processes. Improved understanding of these complex reactions could lead to substantial economic and environmental improvements in oil shale processing.Read moreRead less