Fires of pesticides: New source of polychlorinated dibenzo-p-dioxins and dibenzofurans (PCDD/F) in the environment. This project will quantify the emission of carcinogenic pollutants, produced as a consequence of intended and unintended combustion of pesticides and pesticide-contaminated biomass. The project will identify specific pesticides and agricultural practices (such as burning of sugar cane prior to harvest or burning biomass contaminated with pesticides for energy recovery) which may b ....Fires of pesticides: New source of polychlorinated dibenzo-p-dioxins and dibenzofurans (PCDD/F) in the environment. This project will quantify the emission of carcinogenic pollutants, produced as a consequence of intended and unintended combustion of pesticides and pesticide-contaminated biomass. The project will identify specific pesticides and agricultural practices (such as burning of sugar cane prior to harvest or burning biomass contaminated with pesticides for energy recovery) which may become regulated in Australia. The research will benefit Australia socially, by reducing the emissions of polychlorinated dibenzo-p-dioxins and dibenzofurans and thus protecting the environment and the population, and economically by identifying pesticides that do not produce pollutants in combustion processes and thus do not contaminate biomass intended for energy recovery.Read moreRead less
Low-temperature plasma-catalytic conversion of CH4 and CO2 to alcohols. This project aims to investigate a novel concept of integrated low-temperature plasma and catalytic membrane hybrid reactor system for alcohols production from methane (CH4), carbon dioxide (CO2) and water vapour. This research will combine plasma physics and reaction engineering techniques to develop an innovative gas to liquid technology. The outcomes have the potential to transform the nation's natural gas industry, impro ....Low-temperature plasma-catalytic conversion of CH4 and CO2 to alcohols. This project aims to investigate a novel concept of integrated low-temperature plasma and catalytic membrane hybrid reactor system for alcohols production from methane (CH4), carbon dioxide (CO2) and water vapour. This research will combine plasma physics and reaction engineering techniques to develop an innovative gas to liquid technology. The outcomes have the potential to transform the nation's natural gas industry, improve energy efficiency, and utilise CO2 rich gas resources.Read moreRead less
Micromechanic modelling and analysis of the dynamics of non-spherical particles coupled with fluid flow. This project aims to develop advanced theories and mathematical models to describe the packing and flow of non-spherical particles coupled with fluid flow. This will be achieved through a combined theoretical and experimental program, involving the use of advanced discrete particle simulation and detailed analysis of packing/flow structures, particle-particle and particle-fluid interactions a ....Micromechanic modelling and analysis of the dynamics of non-spherical particles coupled with fluid flow. This project aims to develop advanced theories and mathematical models to describe the packing and flow of non-spherical particles coupled with fluid flow. This will be achieved through a combined theoretical and experimental program, involving the use of advanced discrete particle simulation and detailed analysis of packing/flow structures, particle-particle and particle-fluid interactions at a particle scale. Research outcomes including theories, computer models and simulation techniques will be applied to representative industrial operations of importance to Australia's economic and technological future.Read moreRead less
Understanding the reactivity of pulverised coal at extreme conditions when injected into blast furnaces during PCI. This study aims to improve the understanding and develop a mathematical model of coal combustion during injection into blast furnaces as PCI (pulverised coal injection). The principle economic and social benefits of this project to the community are: (i) Increased efficiency of Blast Furnace operations, resulting in cheaper production of iron in an increasingly globally competitive ....Understanding the reactivity of pulverised coal at extreme conditions when injected into blast furnaces during PCI. This study aims to improve the understanding and develop a mathematical model of coal combustion during injection into blast furnaces as PCI (pulverised coal injection). The principle economic and social benefits of this project to the community are: (i) Increased efficiency of Blast Furnace operations, resulting in cheaper production of iron in an increasingly globally competitive industry, supporting the Australian steel industry and domestic market. And (ii) the potential to impact on process fuel efficiency and reduce CO2 emissions from fossil fuel sources providing a cleaner source of iron for steel production.Read moreRead less
Improving performance of solvent extraction equipment for the minerals processing industry. This project will develop a fundamental understanding of how a new type of solvent extraction column, which was recently introduced to the mining industry, responds to changes in process conditions and operating parameters. This will enable the potential for optimal and efficient use of these assets and ensure a competitive advantage for Australia's biggest export earner.
The elutriation of ultrafine particles according to their density. This study is concerned with exploiting a new and powerful mechanism for separating particles according to their density, with strong potential for recovering and concentrating tens of billions of dollars worth of valuable minerals annually. By coupling the new separation mechanism with a centrifugal force it should be possible to apply gravity separation technology, arguably for the first time, to the recovery of ultrafine parti ....The elutriation of ultrafine particles according to their density. This study is concerned with exploiting a new and powerful mechanism for separating particles according to their density, with strong potential for recovering and concentrating tens of billions of dollars worth of valuable minerals annually. By coupling the new separation mechanism with a centrifugal force it should be possible to apply gravity separation technology, arguably for the first time, to the recovery of ultrafine particles from 200 microns to well below 10 microns, at high separation efficiency, and high feed rates. This study is also ideal for training new researchers, especially at the PhD level, in an area of importance to Australia's economic future. Read moreRead less
Particle classification using a ferrofluid in a non uniform magnetic field. The separation of micron size components of suspensions according to the size and density of the particles is presently an intractable problem. However, by using a magnetized ferrofluid it should be possible to generate unique particle trajectories for each combination of particle size and density. This study investigates the potential of this strategy for separating such particles, laying the foundation for new small-sc ....Particle classification using a ferrofluid in a non uniform magnetic field. The separation of micron size components of suspensions according to the size and density of the particles is presently an intractable problem. However, by using a magnetized ferrofluid it should be possible to generate unique particle trajectories for each combination of particle size and density. This study investigates the potential of this strategy for separating such particles, laying the foundation for new small-scale diagnostic "lab-on a chip" technology that could be used in biotechnology to study whole blood, or in mineral processing to control energy intensive ball mills for mineral particle liberation.Read moreRead less
Use of Parallel Inclined Channels to Enhance Foam Drainage in Ion Flotation. This study is concerned with increasing the rates of foam drainage in flotation processes. The findings will have direct benefit in the field of ion flotation, and will be highly relevant to the flotation of high value minerals worth tens of billions of dollars annually. The Reflux Classifier, a device that employs the Boycott Effect to achieve a significant increase in the effective area of the vessel, will be used. Th ....Use of Parallel Inclined Channels to Enhance Foam Drainage in Ion Flotation. This study is concerned with increasing the rates of foam drainage in flotation processes. The findings will have direct benefit in the field of ion flotation, and will be highly relevant to the flotation of high value minerals worth tens of billions of dollars annually. The Reflux Classifier, a device that employs the Boycott Effect to achieve a significant increase in the effective area of the vessel, will be used. This device has already attracted three national awards in the area of gravity concentration in mineral processing. The study is ideal for training new researchers, especially at the PhD level, given the importance of the field to Australia. Read moreRead less
Engineered functional metal silica membranes for hydrogen processing. This project focuses on hydrogen processing technologies for the petrochemical, agricultural and coal/energy industries. These sectors employ 110,000 people with annual combined revenues of $80 billion. Advanced technologies are vital for the competitiveness of the Australian economy, and to sustain Australia's social stability and economic growth.
Unlocking the catalytic activity of metal oxides through hybrid catalysis. This project aims to understand the interaction of light responsive nano-metals and metal oxide supports in photo-thermal catalysis, and channel light and heat to efficiently drive catalytic reactions. From this understanding, it will develop principles to activate the active site of metal oxides and control catalytic activity with high selectivity and stability. It will use this knowledge to selectively oxidate methane a ....Unlocking the catalytic activity of metal oxides through hybrid catalysis. This project aims to understand the interaction of light responsive nano-metals and metal oxide supports in photo-thermal catalysis, and channel light and heat to efficiently drive catalytic reactions. From this understanding, it will develop principles to activate the active site of metal oxides and control catalytic activity with high selectivity and stability. It will use this knowledge to selectively oxidate methane and oxidative coupling of methane reactions. The expected outcome is an inexpensive green catalysis method for chemical manufacture. This should lower the amount of waste, decrease energy consumption and improve human health, finite global resources and quality of life.Read moreRead less