Establishing advanced networks for air quality sensing and analyses. Establishing advanced networks for air quality sensing and analyses. This project aims to develop innovative, cost-effective, high resolution air quality networks. Recent developments in sensor technologies improve the ability to harvest atmospheric data. This project will develop, validate and implement methods for high sensitivity atmospheric sensing and apply cutting-edge statistical and analytic techniques to the data sets, ....Establishing advanced networks for air quality sensing and analyses. Establishing advanced networks for air quality sensing and analyses. This project aims to develop innovative, cost-effective, high resolution air quality networks. Recent developments in sensor technologies improve the ability to harvest atmospheric data. This project will develop, validate and implement methods for high sensitivity atmospheric sensing and apply cutting-edge statistical and analytic techniques to the data sets, unprecedented in scope and resolution. Outcomes include an open access database to quantify and visualise intra-urban air pollution and human exposure and develop air quality maps and smoke pollution management tools. It is expected to advance the evidence-based management of air as a resource, increasing economic prosperity and enhancing human health and quality of life.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100203
Funder
Australian Research Council
Funding Amount
$326,000.00
Summary
Flow measurement for large-scale industrial aerodynamics. This project aims to research the unsteady aerodynamic wakes of cars, trucks, athletes, turbines and micro-air vehicles. Researchers will use the flow measurement system for large-scale industrial aerodynamics to resolve high speed and large scale industrial flows. The system’s primary objective will be the characterisation of complex, three-dimensional turbulent flows. It is anticipated that the research will lead to reduced aerodynamic ....Flow measurement for large-scale industrial aerodynamics. This project aims to research the unsteady aerodynamic wakes of cars, trucks, athletes, turbines and micro-air vehicles. Researchers will use the flow measurement system for large-scale industrial aerodynamics to resolve high speed and large scale industrial flows. The system’s primary objective will be the characterisation of complex, three-dimensional turbulent flows. It is anticipated that the research will lead to reduced aerodynamic drag in transport and improve wind power generation, ultimately reducing emissions and improving efficiency and national competitiveness in sport. The advanced system will strengthen Australia’s position as an advanced engineering design hub.Read moreRead less
Revolutionising protection against air pollution. This interdisciplinary project aims to develop a personalised air pollution exposure monitoring system, leveraging the ubiquitousness and advancements in mobile phone technology and state of the art miniaturisation of monitoring sensors, data transmission and analysis. Airborne pollution is one of the top contemporary risks faced by humans; however, at present individuals have no way to recognise that they are at risk or need to protect themselve ....Revolutionising protection against air pollution. This interdisciplinary project aims to develop a personalised air pollution exposure monitoring system, leveraging the ubiquitousness and advancements in mobile phone technology and state of the art miniaturisation of monitoring sensors, data transmission and analysis. Airborne pollution is one of the top contemporary risks faced by humans; however, at present individuals have no way to recognise that they are at risk or need to protect themselves. It is expected that the outcome will empower individuals to control and minimise their own exposures. This is expected to lead to significant national socioeconomic benefits and bring global advancement in acquiring and utilising environmental information.Read moreRead less
Future neural electrodes: probing the electrical activity of nerves using 3D graphene networks. This research aims to develop a totally new type of neural electrode that will for the first time, allow reliable and long-term stimulation and recording. The approach incorporates graphene based biomaterials with tunable electrical and biological properties within supportive three-dimensional cellular microenvironments, greatly enhancing the electrical interactions between cells and the electrode. Th ....Future neural electrodes: probing the electrical activity of nerves using 3D graphene networks. This research aims to develop a totally new type of neural electrode that will for the first time, allow reliable and long-term stimulation and recording. The approach incorporates graphene based biomaterials with tunable electrical and biological properties within supportive three-dimensional cellular microenvironments, greatly enhancing the electrical interactions between cells and the electrode. The electrical properties of nerve cells will be probed using our three-dimensional graphene network, providing insight into the the brain-machine interface. This project is important as it directly addresses the inherent limitations of current electrode designs.Read moreRead less
Characterization of mechanical behaviour of TiO2 nanotube thin films. Vertically aligned titanium oxide (TiO2) nanotube arrays have demonstrated remarkable properties for application in dyesensitised solar cell, photocatalysis, self-cleaning coating, purification of pollutants and orthopaedic implants. More excitingly, their architecture and dimensions can be precisely controlled using anodisation of titanium (Ti), creating considerable scientific interest and practical importance. This project ....Characterization of mechanical behaviour of TiO2 nanotube thin films. Vertically aligned titanium oxide (TiO2) nanotube arrays have demonstrated remarkable properties for application in dyesensitised solar cell, photocatalysis, self-cleaning coating, purification of pollutants and orthopaedic implants. More excitingly, their architecture and dimensions can be precisely controlled using anodisation of titanium (Ti), creating considerable scientific interest and practical importance. This project aims to develop novel techniques for determining the mechanical behaviour of TiO2 nanotube arrays and its dependence on crystal structure and geometrical parameters. The outcomes are expected to provide solutions to development of robust TiO2 and other nanotube arrays for broad applications in sustainable energy and tissue engineering.Read moreRead less
Application of tuneable nanofluids in regenerative supercritical power generation. The proposed project combines the simplicity, flexibility, robustness and thermodynamic effectiveness of GRANEXTM cycle with the advances recently made in nanotechnology. If deployed across Australia to recover even 50 per cent of the 11,000 Gigawatt hour annual bioenergy potential, it will generate a revenue stream of approximately $550 million per annum while reducing greenhouse emissions by 14 mega tonne, which ....Application of tuneable nanofluids in regenerative supercritical power generation. The proposed project combines the simplicity, flexibility, robustness and thermodynamic effectiveness of GRANEXTM cycle with the advances recently made in nanotechnology. If deployed across Australia to recover even 50 per cent of the 11,000 Gigawatt hour annual bioenergy potential, it will generate a revenue stream of approximately $550 million per annum while reducing greenhouse emissions by 14 mega tonne, which is about 2.5 per cent of the annual national emissions. The proposed research will place Australia within the forefront of the research and development activities in the field of low grade heat recovery and will clearly contribute the Australian Government's National Research Priority an environmentally sustainable Australia.Read moreRead less
New generation microfluidic devices using light responsive hydrogels. This project aims to develop a new way of fabricating microfluidic devices using light-degradable hydrogels as its core element. This approach would allow researchers to rapidly construct and modify microfluidic devices within their own laboratories, without the need for specialised clean rooms or expensive equipment. The versatility of the microfluidic device is designed to be demonstrated by the manufacture of mature T cells ....New generation microfluidic devices using light responsive hydrogels. This project aims to develop a new way of fabricating microfluidic devices using light-degradable hydrogels as its core element. This approach would allow researchers to rapidly construct and modify microfluidic devices within their own laboratories, without the need for specialised clean rooms or expensive equipment. The versatility of the microfluidic device is designed to be demonstrated by the manufacture of mature T cells, which continues to be a major challenge in stem cell science and which could have fundamental biological and commercial significance.Read moreRead less
Bio-oil/char slurry from biomass for co-combustion in coal power plants: achieving power generation with a significant reduction of CO2 emission. This project will develop an advanced co-combustion technology of bio-oil/char slurry (i.e. bioslurry), prepared from biomass pyrolysis products, and coal in the existing coal-fired power plants for achieving significant CO2 reduction. It will enhance Australia's competitive advantage through high impact scientific and technological innovations.
Enhanced Waste Heat Recovery from Low-grade Heat Sources Using a Novel Supercritical Power Cycle. Compared with conventional technologies for waste heat recovery, GRANEX cycle offers higher thermal efficiencies, better economics and a greater degree of robustness. If deployed ascross the country to recover even 10% of the nation's waste heat, it would reduce greenhouse emissions by 9 mega tonne which is roughly 1.6% of the annual national emissions. That is equivalent to the yearly CO2 emissions ....Enhanced Waste Heat Recovery from Low-grade Heat Sources Using a Novel Supercritical Power Cycle. Compared with conventional technologies for waste heat recovery, GRANEX cycle offers higher thermal efficiencies, better economics and a greater degree of robustness. If deployed ascross the country to recover even 10% of the nation's waste heat, it would reduce greenhouse emissions by 9 mega tonne which is roughly 1.6% of the annual national emissions. That is equivalent to the yearly CO2 emissions from 648,000 houses or 2 million cars. The proposed research will place Australia within the forefront of the research and development activities in the field of waste heat recovery and will clearly contribute to the Federal Government’s effort in the National Research Priority 1, An Environmentally Sustainable Australia.Read moreRead less
Shale rock characterisation using Nuclear Magnetic Resonance. This project aims to assess the viability of potential shale oil and gas reserves, using Nuclear Magnetic Resonance (NMR) core analysis and well logging techniques to characterise shale samples. Shale oil and gas reserves have the potential to provide a rapidly dispatchable energy source, which could play a key role as a transition fuel to renewable energy. The project will develop techniques to deliver quantitative fluid typing, prod ....Shale rock characterisation using Nuclear Magnetic Resonance. This project aims to assess the viability of potential shale oil and gas reserves, using Nuclear Magnetic Resonance (NMR) core analysis and well logging techniques to characterise shale samples. Shale oil and gas reserves have the potential to provide a rapidly dispatchable energy source, which could play a key role as a transition fuel to renewable energy. The project will develop techniques to deliver quantitative fluid typing, producible porosity, pore sizes and permeability measurements for shale samples, which could be used in the shale gas and oil industry. These techniques will improve the predictability of shale field developments that better inform their economic and environmental impact.
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