Role of Reactive Particles in Explosive Emulsions. Concentrated water-in oil explosive emulsions are widely used in the minerals industry because they are cheap, easily detonated and relatively safe to handle. Their explosive energy can be significantly increased when reactive particles are introduced into the emulsion matrix. To do this, the interaction between the solid, oil, and water phases needs to be optimised. This investigation will increase our basic understanding of the physical and ch ....Role of Reactive Particles in Explosive Emulsions. Concentrated water-in oil explosive emulsions are widely used in the minerals industry because they are cheap, easily detonated and relatively safe to handle. Their explosive energy can be significantly increased when reactive particles are introduced into the emulsion matrix. To do this, the interaction between the solid, oil, and water phases needs to be optimised. This investigation will increase our basic understanding of the physical and chemical interactions that occur between the particle and the oil-water interface, and develop a more efficient explosive that can be produced continuously on a commercial scale.Read moreRead less
Friction-based modelling of the dynamics of nanoconfined fluid mixtures. This project will transform the molecular science of fluid transport in nanoconfined spaces by delivering a tool that will be critical to the development of emerging nanotechnologies. The tool will embed a novel theory in a framework for modelling transport over all scales from nano- to macroscopic. The project will have strong benefits for the advancement of leading-edge fundamental research and in its relevance to a numbe ....Friction-based modelling of the dynamics of nanoconfined fluid mixtures. This project will transform the molecular science of fluid transport in nanoconfined spaces by delivering a tool that will be critical to the development of emerging nanotechnologies. The tool will embed a novel theory in a framework for modelling transport over all scales from nano- to macroscopic. The project will have strong benefits for the advancement of leading-edge fundamental research and in its relevance to a number of novel nanotechnologies. It will be particularly relevant to scientific and industrial developments exploiting new nanomaterials such as AlPO4-25, carbon molecular sieves and carbon nanotubes, as well as in nanofluidics.Read moreRead less
Improved Nanoscale and Molecular Models for Nanostructured Carbons, and their Applications in Simulation of Confined Fluids. This project has a multitude of benefits for Australia, a key one of which is the promotion of cross-disciplinary interaction and collaboration to conduct leading edge research in a technologically important area. In addition the project will utilize two PhD students who will be trained in research, and gain a broad range of skills in this multifaceted project involving t ....Improved Nanoscale and Molecular Models for Nanostructured Carbons, and their Applications in Simulation of Confined Fluids. This project has a multitude of benefits for Australia, a key one of which is the promotion of cross-disciplinary interaction and collaboration to conduct leading edge research in a technologically important area. In addition the project will utilize two PhD students who will be trained in research, and gain a broad range of skills in this multifaceted project involving theory, simulation and experiment. The research, grounded in molecular fundamentals, will also lead to the development of advanced tools for adsorption process modelling, useful in process design and scale-up, and contribute to Goal 1 of National Priority Area 3: Frontier Technologies for Building and Transforming Australian Industries.Read moreRead less
Transport Processes in Flexible Porous Materials for Gas Separation and Storage. This project seeks to understand the mechanisms of transport processes in flexible porous materials, which have great potential in gas separation and storage. Coal and natural gas are important to the Australian economy, and the potential applications of flexible porous materials, such as air separation and hydrogen storage, are crucial for Australia to use coal and natural gas cleanly. The analysis method to be dev ....Transport Processes in Flexible Porous Materials for Gas Separation and Storage. This project seeks to understand the mechanisms of transport processes in flexible porous materials, which have great potential in gas separation and storage. Coal and natural gas are important to the Australian economy, and the potential applications of flexible porous materials, such as air separation and hydrogen storage, are crucial for Australia to use coal and natural gas cleanly. The analysis method to be developed is useful not only to gas separation and storage, but also to hydrogeology and soil science in Australia.Read moreRead less
Gassing Mechanism and Stability of Foamed Explosive Emulsions. Mining of minerals such as coal involves crushing the surrounding rock strata, or the mineral ore itself, with emulsion explosives. One of the most important properties determining suitability of an emulsion explosive to a particular mining operation is its velocity of detonation, which can be adjusted by varying the number and size of air bubbles distributed in the emulsion matrix. The present project aims to develop new ways of g ....Gassing Mechanism and Stability of Foamed Explosive Emulsions. Mining of minerals such as coal involves crushing the surrounding rock strata, or the mineral ore itself, with emulsion explosives. One of the most important properties determining suitability of an emulsion explosive to a particular mining operation is its velocity of detonation, which can be adjusted by varying the number and size of air bubbles distributed in the emulsion matrix. The present project aims to develop new ways of generating air bubbles, to gain fundamental understanding of the foaming mechanism in currently used gassing techniques, and to invent ways to stabilise large bubbles within the emulsion. The project will provide scientific underpinning for the development of a new range of emulsion explosives manufactured by Orica for Australian and international markets, maintaining the Orica's position as a leader in the field of emulsion explosives.Read moreRead less
Novel technology to sensitise emulsion explosives. The project will develop a new technology for more efficient and safer extraction of minerals. It will extend the application of emulsion explosives to low-temperatures and will eliminate the heating of emulsion blasting agents during transport. Since mining operations are located in regional areas, the project will bring benefits to local and rural communities. The project will also generate new knowledge on the behaviour and stability of th ....Novel technology to sensitise emulsion explosives. The project will develop a new technology for more efficient and safer extraction of minerals. It will extend the application of emulsion explosives to low-temperatures and will eliminate the heating of emulsion blasting agents during transport. Since mining operations are located in regional areas, the project will bring benefits to local and rural communities. The project will also generate new knowledge on the behaviour and stability of three-phase systems that contain very small gas bubbles. In addition to its fundamental importance, this knowledge can be carried over to food and cosmetic industries to facilitate the development of new products.Read moreRead less
Microfluidic Studies of Stimuli-Responsive Emulsions. Breakthrough 'stimuli-responsive interface technology' has been developed in Australia to allow better control over emulsions, which are oil-in-water mixtures used widely in everyday products such as medicines. This project will increase our understanding of this new technology, by examining how the chemistry of the molecules at the interface interacts with fluid behaviour when the emulsion is made. The research will employ miniature lab-on-a ....Microfluidic Studies of Stimuli-Responsive Emulsions. Breakthrough 'stimuli-responsive interface technology' has been developed in Australia to allow better control over emulsions, which are oil-in-water mixtures used widely in everyday products such as medicines. This project will increase our understanding of this new technology, by examining how the chemistry of the molecules at the interface interacts with fluid behaviour when the emulsion is made. The research will employ miniature lab-on-a-chip systems, to give engineers and scientists design rules for this new technology, opening the way to new products that will improve our everyday lives. One immediate product to be researched is 'precision' double emulsions, which show unique properties for the delivery of chemotherapy medicines.Read moreRead less
Benign fabrication of microfluidic hydrogel for improved artificial vasculature in bone implants. We will create a benign technology for synthesising microfluidic hydrogels to generate artificial vascultures in bone implants. It is a critical step to enable the use of tissue-engineered vital organs, such as bone, heart and kidney in patients with end-stage organ failure. Thicker scaffolds will be possible, as the vasculature will provide nutrients and oxygen for cells to grow into 3D scaffolds. ....Benign fabrication of microfluidic hydrogel for improved artificial vasculature in bone implants. We will create a benign technology for synthesising microfluidic hydrogels to generate artificial vascultures in bone implants. It is a critical step to enable the use of tissue-engineered vital organs, such as bone, heart and kidney in patients with end-stage organ failure. Thicker scaffolds will be possible, as the vasculature will provide nutrients and oxygen for cells to grow into 3D scaffolds. It will promote capacity of Australia for manufacturing global biomaterial products for tissue engineering. We will also develop in-situ imaging analytical protocols for the rapid analysis of broad arrays of functional molecules, with significant bearing on BioMEMS design to develop methods for diagnosis of fatal diseases.Read moreRead less
Mechanisms of Ammonium Nitrate Decomposition and Stability of Industrial Explosives in Reactive Mining Grounds. This project is designed to probe reaction mechanisms of ammonium nitrate based explosives with pyritic shales commonly found in overburdens of mineral deposits, and to study the influence of various factors, such as mineralogical characteristics, carbonaceous materials, weathering, pH values and application of various inhibition agents, on the decomposition and stability of ammonium n ....Mechanisms of Ammonium Nitrate Decomposition and Stability of Industrial Explosives in Reactive Mining Grounds. This project is designed to probe reaction mechanisms of ammonium nitrate based explosives with pyritic shales commonly found in overburdens of mineral deposits, and to study the influence of various factors, such as mineralogical characteristics, carbonaceous materials, weathering, pH values and application of various inhibition agents, on the decomposition and stability of ammonium nitrate. Ammonium nitrate crystallisation, which significantly reduces the stability of emulsion explosives, will be examined using both chemical and microscopic tools. The outcomes of this research will provide a scientific basis that underpins the development of safe and cost-effective explosives for applications in dangerous reactive mining grounds.Read moreRead less
Analysing Instabilities in Complex Combustion Models for Different Geometrical Configurations. Anyone who has gazed into a fire will appreciate the complexity of combustion. To date only the simplest of models have been comprehensively analysed. This project, which aims to analyse more complex combustion models, will address some of the fundamental issues of combustion theory. Results from this project will lead to a better understanding of combustion processes, with the potential to prevent exp ....Analysing Instabilities in Complex Combustion Models for Different Geometrical Configurations. Anyone who has gazed into a fire will appreciate the complexity of combustion. To date only the simplest of models have been comprehensively analysed. This project, which aims to analyse more complex combustion models, will address some of the fundamental issues of combustion theory. Results from this project will lead to a better understanding of combustion processes, with the potential to prevent explosions in reactors and storage tanks. Other potential applications range from bushfires to the manufacture of exotic materials. Furthermore, the novel mathematical techniques developed in this project can be easily adapted to other types of systems such as those used in biology (eg. epidemiology and tumour growth), economics, physics etc. Read moreRead less