High-order conservative multiscale computation of elliptic problems in composite materials and porous media. The proposed technology will improve the design and performance of a wide range of mechanisms and industrial processes involving heterogeneous media, from composite materials to water filtration and recycling. Our researchers in computational mechanics will gain further opportunities to extend the advances this project will make.
Direct simulation of composite microstructures in fluid and elastic media. The proposed innovative computational methodology will improve the design and performance of a wide range of mechanisms and industrial processes involving particulate inclusions, from engineering to biological applications. The resultant technology will make a contribution to maintain and enhance Australia's role in the development of advanced engineering materials through manipulating their composite microstructures. The ....Direct simulation of composite microstructures in fluid and elastic media. The proposed innovative computational methodology will improve the design and performance of a wide range of mechanisms and industrial processes involving particulate inclusions, from engineering to biological applications. The resultant technology will make a contribution to maintain and enhance Australia's role in the development of advanced engineering materials through manipulating their composite microstructures. The proposed computational method will also lead to new opportunities for Australian companies that develop computer simulation software. Our researchers in computational mechanics will gain further opportunities to extend the advances this project will make.Read moreRead less
Regenerable CO2 adsorbing materials for zero emission power generation systems. The new CAM material developed in this project will remove one of the major technical obstacles to the adoption of the zero emission power generation systems, leading to solutions to CO2 management without economic penalty.This project also contributes to building capacity in emerging advanced energy technologies, by keeping informed about major technology developments in areas of Australia's strategic interest.
Novel cathode materials for low-temperature solid-oxide fuel cells. This project will produce novel mixed ionic and electronic conducting cathodes to reduce the operating temperature of solid-oxide fuel cells (SOFC). The technology developed is of ultimate benefit to the Australian electricity consumer. It can accelerate the development of low-cost SOFCs that can serve in distributed power generation. The benefits include increased reliability of the power supply and substantive cost savings thr ....Novel cathode materials for low-temperature solid-oxide fuel cells. This project will produce novel mixed ionic and electronic conducting cathodes to reduce the operating temperature of solid-oxide fuel cells (SOFC). The technology developed is of ultimate benefit to the Australian electricity consumer. It can accelerate the development of low-cost SOFCs that can serve in distributed power generation. The benefits include increased reliability of the power supply and substantive cost savings through increased efficiency of the conversion of gas to electricity. Depending on the level of market penetration, the broad deployment of SOFCs can save well over $100 million/year for the Australian consumer. The environmentally friendly technologies will also be beneficial for reducing pollution and greenhouse gases in Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560716
Funder
Australian Research Council
Funding Amount
$864,610.00
Summary
A National T-ray Facility. T-rays are between microwaves and infrared on the electromagnetic spectrum. Recently, advances in femtosecond lasers enabled access to T-ray frequencies, producing an important new imaging modality for non-invasive sensing of materials and structures. Internationally, T-rays represent a rich new science leading to advanced forms of biophotonics, biomedical imaging and spectroscopy. Non-invasive T-ray diagnostics of nano- and bio-materials are being hotly pursued. The o ....A National T-ray Facility. T-rays are between microwaves and infrared on the electromagnetic spectrum. Recently, advances in femtosecond lasers enabled access to T-ray frequencies, producing an important new imaging modality for non-invasive sensing of materials and structures. Internationally, T-rays represent a rich new science leading to advanced forms of biophotonics, biomedical imaging and spectroscopy. Non-invasive T-ray diagnostics of nano- and bio-materials are being hotly pursued. The outcome will be a strategically important Australian T-ray facility that will provide immediate and transparent nationwide access. Historically, industry is transformed every time a new part of the electromagnetic spectrum becomes accessible - T-rays are the next frontier.Read moreRead less
Theoretical Study of Functionalized Boron Nitride Nanotubes and Their Application as Gas Sensor. The gas sensors to be studied in this project can be deployed for a variety of applications, such as environmental monitoring, sensing in chemical processing plant, and gas detection for counter-terrorism, this project thus can significantly contribute to environmental protection, national security, and agriculture and pharmaceutical industries in Australia. Such mechanism understanding will also be ....Theoretical Study of Functionalized Boron Nitride Nanotubes and Their Application as Gas Sensor. The gas sensors to be studied in this project can be deployed for a variety of applications, such as environmental monitoring, sensing in chemical processing plant, and gas detection for counter-terrorism, this project thus can significantly contribute to environmental protection, national security, and agriculture and pharmaceutical industries in Australia. Such mechanism understanding will also be very useful for exploring the applications of BNNTs in nano-optical-magnetic devices, energy storage and biomaterials This project will also be important for keeping Australia in the frontier area in the research areas of nanotubes.Read moreRead less
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
Nano-machining of diamond-like carbon (DLC): Scientific basis and technical potential. Nanotechnology will be the basis for the next post-industrial revolution, and will be the main driver of future national economies. It is crucially important that at the very least Australia is a significant niche player in those developments. The project represents an effort to promote those goals.
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