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
Multi-component Gas Transport in Deep Coal. The understanding of multi-component gas flow in coal underlies the use, management and optimization of deep coal as an economic resource for methane recovery, CO2 sequestration, pipeline gas storage and underground gasification. This project will develop a predictive reservoir flow model for deep coal behavior under asymmetric, dynamically evolving internal and external stresses, during multi-component gas release or injection. A confluence of new too ....Multi-component Gas Transport in Deep Coal. The understanding of multi-component gas flow in coal underlies the use, management and optimization of deep coal as an economic resource for methane recovery, CO2 sequestration, pipeline gas storage and underground gasification. This project will develop a predictive reservoir flow model for deep coal behavior under asymmetric, dynamically evolving internal and external stresses, during multi-component gas release or injection. A confluence of new tools including a large sample, high pressure, triaxial stress permeameter, and micron resolved 3D reconstruction of the coal cleat and pore structure, will provide physical parameters to the fundamentally based, competitive transport and adsorption/desorption model.Read moreRead less
Anisotropic behaviour of coal for coalbed methane recovery and CO2 geosequestration. Amongst the cheapest and safest options for clean energy are to use natural gas from coal seams for electricity and fuel production and then permanently store carbon dioxide within the depleted seams. This requires information about the underground behaviour of coal at a level of detail which is not available. In particular, the directional and dynamic response of coal to changes in pressure, stress and gas in ....Anisotropic behaviour of coal for coalbed methane recovery and CO2 geosequestration. Amongst the cheapest and safest options for clean energy are to use natural gas from coal seams for electricity and fuel production and then permanently store carbon dioxide within the depleted seams. This requires information about the underground behaviour of coal at a level of detail which is not available. In particular, the directional and dynamic response of coal to changes in pressure, stress and gas interactions is required, which is the subject of this project. Coal bed methane is rapidly growing into a multi-billion dollar industry for Australia. The geosequestration of carbon dioxide in deep coal is widely recognised presenting a secure and economical opportunity for greenhouse gas control. Read moreRead less
Sequestration of CO2 with enhanced methane recovery from deep coal. Coal and gas represent the main energy source for the Australian and many other national economies into the foreseeable future. The continuing use of these critical resources requires that greenhouse gas emission issues be addressed. Any serious attempt to achieve reduced emission of CO2 from power generation requires sequestration as a necessary element. A plausible method for cost effective sequestration of large amounts of ....Sequestration of CO2 with enhanced methane recovery from deep coal. Coal and gas represent the main energy source for the Australian and many other national economies into the foreseeable future. The continuing use of these critical resources requires that greenhouse gas emission issues be addressed. Any serious attempt to achieve reduced emission of CO2 from power generation requires sequestration as a necessary element. A plausible method for cost effective sequestration of large amounts of CO2 is by geological fixing in deep, unminable coal. The key technological and scientific issues regarding capacity, rate, technical viability and site selection form the basis of this proposal.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
Terahertz Spectroscopy of Mass-Manufactured Viral Vaccines. The breakthrough vaccine for cervical cancer proves that new and exciting products are on the way to treat and protect against previously untouchable diseases. Similar products for bird flu are being researched, and new manufacturing methods are urgently needed to get this science to market at a price that people can afford. However, manufacturing innovation in the pharmaceutical industry is constrained by a lack of methods for product ....Terahertz Spectroscopy of Mass-Manufactured Viral Vaccines. The breakthrough vaccine for cervical cancer proves that new and exciting products are on the way to treat and protect against previously untouchable diseases. Similar products for bird flu are being researched, and new manufacturing methods are urgently needed to get this science to market at a price that people can afford. However, manufacturing innovation in the pharmaceutical industry is constrained by a lack of methods for product analysis. In this project engineers will devise advanced methods to fingerprint these new vaccine products, ensuring that manufacturing processes can be improved without compromising safety. These new analytical techniques will potentially lead to new low-cost vaccine products made in Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989675
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Interface-specific facility for quantifying adsorption and structures at particulate interfaces. The facility will be used by the collaborating universities to investigate adsorption and interface properties with great precision, and to develop new and improved technologies for coal and mineral processing, saline water utilisation, water desalination, energy production and environment protection. In particular, the project will investigate innovative ways of using ion-interface interactions in ....Interface-specific facility for quantifying adsorption and structures at particulate interfaces. The facility will be used by the collaborating universities to investigate adsorption and interface properties with great precision, and to develop new and improved technologies for coal and mineral processing, saline water utilisation, water desalination, energy production and environment protection. In particular, the project will investigate innovative ways of using ion-interface interactions in saline water for cleaning coal and recovering value minerals by flotation, and for improving dissolved air flotation used in water treatment and desalination to produce drinking water. The project will further investigate novel ways of capturing CO2, storing natural gases and hydrogen, and tailoring nutrient nano-crystals for foliar delivery.Read moreRead less
New dispersants for improved agrochemical and allied formulations. This project will deliver substantial benefits for national regional communities and the environment through improved agrochemical dispersion, and reduced pesticide and water use. This project will deliver improved products for agrochemicals and animal food, bringing significant agricultural advantages to Australia. This will help Huntsman with cutting-edge technologies in manufacturing agrochemical and related products for the n ....New dispersants for improved agrochemical and allied formulations. This project will deliver substantial benefits for national regional communities and the environment through improved agrochemical dispersion, and reduced pesticide and water use. This project will deliver improved products for agrochemicals and animal food, bringing significant agricultural advantages to Australia. This will help Huntsman with cutting-edge technologies in manufacturing agrochemical and related products for the national and global markets. We will provide advanced training for postgraduate and research personnel that will be sought-after by the agrochemical and allied industries.Read moreRead less
Phase stability of biomass fast pyrolysis bio-oil: behaviour and control. This project aims to carry out a systematic investigation into the phase behaviour and control of biomass fast pyrolysis into bio-oil and its derived fuels. The project addresses the major problem of fuel phase separation during processing and handling that cause significant operational challenges, for example pumping difficulties and line clogging, during storage, transport and applications of these fuels. The outcomes in ....Phase stability of biomass fast pyrolysis bio-oil: behaviour and control. This project aims to carry out a systematic investigation into the phase behaviour and control of biomass fast pyrolysis into bio-oil and its derived fuels. The project addresses the major problem of fuel phase separation during processing and handling that cause significant operational challenges, for example pumping difficulties and line clogging, during storage, transport and applications of these fuels. The outcomes include the discovery of fundamental knowledge on the phase structure, stability and behaviour of the products of biomass fast pyrolysis bio-oil and its derived fuels and the development of essential engineering tools for predicting and controlling phase behaviour and stability of these fuels.Read moreRead less
Oxy-cofiring of bio-slurry and coal for carbon-negative power generation. This project aims to study co-firing characteristics of bio-slurry fuels and coal under oxy-pulverised-fuel (oxy-PF) conditions. Oxy-PF stationary systems can capture the renewable carbon embedded in bio-slurry fuel from biomass pyrolysis for sequestration, leading to carbon-negative power generation. The expected outcomes are critical knowledge and data regarding the underlying thermochemical reactions responsible for the ....Oxy-cofiring of bio-slurry and coal for carbon-negative power generation. This project aims to study co-firing characteristics of bio-slurry fuels and coal under oxy-pulverised-fuel (oxy-PF) conditions. Oxy-PF stationary systems can capture the renewable carbon embedded in bio-slurry fuel from biomass pyrolysis for sequestration, leading to carbon-negative power generation. The expected outcomes are critical knowledge and data regarding the underlying thermochemical reactions responsible for the co-pyrolysis, volatiles/char co-firing and ash formation from bio-slurry/coal co-firing under oxy-PF conditions. This is expected to enhance Australia's competitive advantage in clean power generation through high-impact scientific and technological innovations, and strengthen the related knowledge and skill base in the country.Read moreRead less