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
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
Special Research Initiatives - Grant ID: SR0354467
Funder
Australian Research Council
Funding Amount
$20,000.00
Summary
New Frontiers in Structural Health Monitoring. In-situ Structural Health Monitoring (SHM) is part of a current revolution in smart-structures technologies promising quantum gains in performance, endurance and cost-efficient maintenance for high-value assets. The aim of the proposed network is to provide a platform for collaborative, multidisciplinary research, research training and innovation by integrating currently disparate programs in SHM, since the high investment costs for the development ....New Frontiers in Structural Health Monitoring. In-situ Structural Health Monitoring (SHM) is part of a current revolution in smart-structures technologies promising quantum gains in performance, endurance and cost-efficient maintenance for high-value assets. The aim of the proposed network is to provide a platform for collaborative, multidisciplinary research, research training and innovation by integrating currently disparate programs in SHM, since the high investment costs for the development of next generation smart technologies make a collaborative approach an absolute necessity. Its significance includes the efficient generation of world-class research outcomes in the key technologies enabling this revolution, viz. (i) sensor technologies; (ii) multifunctional materials; and (iii) intelligent systems, and the timely dissemination of these outcomes to Australian industry.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.
Effective and accurate model dynamics, deterministic and stochastic, across multiple space and time scales. A persistent feature of complex systems in engineering and science is the emergence of macroscopic, coarse grained, coherent behaviour from the interactions of microscopic agents (molecules, cells, grains) and with their environment. In current modeling, ranging from ecology to materials science, the underlying microscopic mechanisms are often known, but the closures to translate microscal ....Effective and accurate model dynamics, deterministic and stochastic, across multiple space and time scales. A persistent feature of complex systems in engineering and science is the emergence of macroscopic, coarse grained, coherent behaviour from the interactions of microscopic agents (molecules, cells, grains) and with their environment. In current modeling, ranging from ecology to materials science, the underlying microscopic mechanisms are often known, but the closures to translate microscale knowledge to a system level macroscopic description are rarely available in closed form. Our novel methodology will explore this stumbling block, and promises to radically change the modeling, exploration and understanding of multiscale complex system behaviour.Read moreRead less
Novel Graphitic Mesoporous Carbon Materials for Next Generation Carbon Catalyst Supports and Carbon Electrodes. This project will bring about direct application benefits in terms of disclosing novel graphitic mesoporous carbons with high accessible surface area and graphitic framework as catalyst supports and electrode materials. This would lead to advanced processes important to the Australian energy and environmental industries, such as electrical double layer capacitors, greenhouse reduction ....Novel Graphitic Mesoporous Carbon Materials for Next Generation Carbon Catalyst Supports and Carbon Electrodes. This project will bring about direct application benefits in terms of disclosing novel graphitic mesoporous carbons with high accessible surface area and graphitic framework as catalyst supports and electrode materials. This would lead to advanced processes important to the Australian energy and environmental industries, such as electrical double layer capacitors, greenhouse reduction by hydrogen fuel, and hydrodesulfurization of diesel fuels. The techniques and synthesis strategies developed in this project are also applicable to creating other graphitic mesoporsous carbons important to advanced sensors, fuel cells and optoelectronic applications. Read moreRead less
Modelling of multiscale systems in engineering and science supports large-scale equation-free simulations and analysis. A persistent feature of complex systems in engineering and science is the emergence of macroscopic, coarse grained, coherent behaviour from the interactions of microscopic agents (molecules, cells) and with their environment. In current modeling, ranging from ecology to materials science, the underlying microscopic mechanisms are known, but the closures to translate microscale ....Modelling of multiscale systems in engineering and science supports large-scale equation-free simulations and analysis. A persistent feature of complex systems in engineering and science is the emergence of macroscopic, coarse grained, coherent behaviour from the interactions of microscopic agents (molecules, cells) and with their environment. In current modeling, ranging from ecology to materials science, the underlying microscopic mechanisms are known, but the closures to translate microscale knowledge to a system level macroscopic description are rarely available in closed form. Our novel, equation free, computational methodologies will circumvent this stumbling block, and promises to radically change the modeling, exploration and understanding of complex system behavior. We continue to develop this powerful computational methodology. 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
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