Could porous pavements be a part of the urban water solution? With water demand in Australia approaching, and sometimes exceeding, limits of sustainability, there is a pressing need to find alternative water sources. At the same time, urban stormwater pollution remains a major environmental threat. These problems are particularly difficult in urban areas, due to space constraints. This project will test and refine porous pavement technology, which could help solve the 'urban water problem'. R ....Could porous pavements be a part of the urban water solution? With water demand in Australia approaching, and sometimes exceeding, limits of sustainability, there is a pressing need to find alternative water sources. At the same time, urban stormwater pollution remains a major environmental threat. These problems are particularly difficult in urban areas, due to space constraints. This project will test and refine porous pavement technology, which could help solve the 'urban water problem'. Replacing impervious areas with porous pavements will allow urban stormwater to be treated and harvested for re-use. Waterways will be protected from pollution, and the vast quantity of urban stormwater generated (similar to the total reticulated water supplied in Australia) can be harvested to sustain cities.Read moreRead less
Optical fibre photoreactor for removing airborne molecular contaminants and volatile organic carbons for semiconductor fabrication and fuel cell applications. The collaboration integrates concepts from photocatalysis, optical fibre technology and filtration, to solve important issues in the semiconductor fabrication and fuel cell industries. The project will place Australia amongst the world-leaders in novel integrated photocatalytic/filtration techniques and provide significant opportunities fo ....Optical fibre photoreactor for removing airborne molecular contaminants and volatile organic carbons for semiconductor fabrication and fuel cell applications. The collaboration integrates concepts from photocatalysis, optical fibre technology and filtration, to solve important issues in the semiconductor fabrication and fuel cell industries. The project will place Australia amongst the world-leaders in novel integrated photocatalytic/filtration techniques and provide significant opportunities for penetration, in particular, into the US filtration market. The collaboration will afford young Australian-based researchers the opportunity to access technology, expertise and knowledge developed in the US, which is currently unavailable in Australia. It will strengthen ties between UNSW and UMN and provide opportunities for further collaboration.Read moreRead less
Restoring hydrological connectivity of surface and ground waters: Biogeochemical processes and environmental benefits for river landscapes. This project examines the restoration of lateral hydrological connectivity to improve floodplain structure and function. The connections between stream flows and both shallow groundwaters and floodplains are critical in sustaining river landscapes. Degrading land and water management practices compounded by natural climatic extremes have severed this link. ....Restoring hydrological connectivity of surface and ground waters: Biogeochemical processes and environmental benefits for river landscapes. This project examines the restoration of lateral hydrological connectivity to improve floodplain structure and function. The connections between stream flows and both shallow groundwaters and floodplains are critical in sustaining river landscapes. Degrading land and water management practices compounded by natural climatic extremes have severed this link. Restoring hydrological connectivity is vital for replenishing groundwater storage and increasing base flows that affect fundamental riverine processes. Using an innovative approach to sustainable agriculture, our project unites multidisciplinary scientific and industry expertise to investigate the biogeochemical and biophysical effects of secondary floodplain channels and in-stream structures on riverine groundwater processes.Read moreRead less
Development of High Performance Nanocomposite Filtration Membranes: Fabrication and Fouling Mechanisms. This project will develop high performance membranes for the filtration of water and wastewater using novel nanotechnology processes. This will reduce the costs and environmental impact of water treatment and risk from low-level chemical contaminants such as micropollutants. The project will also provide an enhanced technology base for producing low cost, hybrid inorganic-organic materials fo ....Development of High Performance Nanocomposite Filtration Membranes: Fabrication and Fouling Mechanisms. This project will develop high performance membranes for the filtration of water and wastewater using novel nanotechnology processes. This will reduce the costs and environmental impact of water treatment and risk from low-level chemical contaminants such as micropollutants. The project will also provide an enhanced technology base for producing low cost, hybrid inorganic-organic materials for widespread environmental, agricultural and food applications.Read moreRead less
Special Research Initiatives - Grant ID: SR0354781
Funder
Australian Research Council
Funding Amount
$40,000.00
Summary
Research Network for Engineering a Secure Australia (RNESA). The Research Network for Engineering a Secure Australia (RNESA) is a multi-disciplinary collaboration established to strengthen Australia's science and technology capacity for protecting the Nation's critical infrastructure from natural or human-caused disasters. RNESA will facilitate a knowledge sharing network for government, universities and the private sector to produce innovative engineering solutions to the emerging security prob ....Research Network for Engineering a Secure Australia (RNESA). The Research Network for Engineering a Secure Australia (RNESA) is a multi-disciplinary collaboration established to strengthen Australia's science and technology capacity for protecting the Nation's critical infrastructure from natural or human-caused disasters. RNESA will facilitate a knowledge sharing network for government, universities and the private sector to produce innovative engineering solutions to the emerging security problems relating to the safety of critical infrastructure. This initiative will draw together researchers across disciplines to identify a roadmap for future R&D in this area. RNESA's final outcomes will lead to multi-hazard mitigation strategies and a real-time crisis support network to enable the nation to manage potential disasters.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882388
Funder
Australian Research Council
Funding Amount
$130,000.00
Summary
Advanced characterisation of organics and biopolymers in water and wastewater treatment. Although membrane technology is increasingly used for water production, wastewater treatment and reclamation, fouling by complex bio-organics is a major limitation. The liquid chromatography-organic carbon detection and the Flow FFF equipments give detailed analyses of the complex organics, thereby helping to understand the fouling and organic removal mechanisms allowing process optimisation. The availabilit ....Advanced characterisation of organics and biopolymers in water and wastewater treatment. Although membrane technology is increasingly used for water production, wastewater treatment and reclamation, fouling by complex bio-organics is a major limitation. The liquid chromatography-organic carbon detection and the Flow FFF equipments give detailed analyses of the complex organics, thereby helping to understand the fouling and organic removal mechanisms allowing process optimisation. The availability of these equipments will ramatically improve the quality of a number of research projects currently funded and being developed in Australia. This equipment would provide necessary infrastructure to keep Australian researchers world leaders in this research field (one of Australian top research priorities) and attract national and international collaborations.Read moreRead less
Wave Climate in the Southern Great Barrier Reef. Sea surface roughness has a major influence on global climate modelling. This project will provide a better understanding of the variability of sea waves in coastal waters. New technology of HF ocean radar can map wave fields over coastal waters and thus fill a gap between the open ocean satellite measurements and the point measurements from wave buoys. In this project we will improve the analysis of the radar echoes to produce sea wave spectra, a ....Wave Climate in the Southern Great Barrier Reef. Sea surface roughness has a major influence on global climate modelling. This project will provide a better understanding of the variability of sea waves in coastal waters. New technology of HF ocean radar can map wave fields over coastal waters and thus fill a gap between the open ocean satellite measurements and the point measurements from wave buoys. In this project we will improve the analysis of the radar echoes to produce sea wave spectra, and evaluate focussing of waves by complex currents on the continental shelf to help improve wave forecasting in coastal waters. The HF radar will be used to experimentally test current theories of wind wave spreading.Read moreRead less
Evaluating the role of buffer strips in reducing soil erosion and sediment delivery to water bodies. The role of vegetative buffer strips in reducing soil erosion and sediment delivery to water bodies is well established, but the physical processes and their interactions involved are not well understood. These hydraulic, sediment/chemical transport processes will be modelled from physical principles, recognising that the multi-size characteristics of soil plays a vital role in buffer strip effec ....Evaluating the role of buffer strips in reducing soil erosion and sediment delivery to water bodies. The role of vegetative buffer strips in reducing soil erosion and sediment delivery to water bodies is well established, but the physical processes and their interactions involved are not well understood. These hydraulic, sediment/chemical transport processes will be modelled from physical principles, recognising that the multi-size characteristics of soil plays a vital role in buffer strip effectiveness. This model will be validated using new and existing data sources, including both controlled experiments and field data obtained in Australia and overseas. A user friendly version of the model will be developed for farm managers and advisory services as a design tool.Read moreRead less
Progressive liquefaction within marine sediments: comparison between geo-centrifuge modelling, full-scale wave tank tests and numerical modelling. The evaluation of wave-induced liquefaction within the marine sediment is particularly important for coastal and geotechnical engineers involved in the design of foundation around coastal structures. The proposed study will integrate the existing knowledge from the aspects of coastal and geotechnical engineering with that of overseas experts to provid ....Progressive liquefaction within marine sediments: comparison between geo-centrifuge modelling, full-scale wave tank tests and numerical modelling. The evaluation of wave-induced liquefaction within the marine sediment is particularly important for coastal and geotechnical engineers involved in the design of foundation around coastal structures. The proposed study will integrate the existing knowledge from the aspects of coastal and geotechnical engineering with that of overseas experts to provide coastal engineers with an effective tool for the design of foundations around marine structures. It will also assist in reducing the risk of potential environmental damage caused by failure of marine structures.Read moreRead less
Mathematical and mechanical modeling of nano particulate flow. Nano particulates are the basis for many new technologies, including coatings in the electronics industry, composite materials and medical and pharmaceutical applications. Worldwide industrial competition is increasingly determined by our capacity to handle such highly cohesive materials, and to exploit their novel physical, chemical and mechanical characteristics. Devising handling mechanisms and understanding nano particulate flows ....Mathematical and mechanical modeling of nano particulate flow. Nano particulates are the basis for many new technologies, including coatings in the electronics industry, composite materials and medical and pharmaceutical applications. Worldwide industrial competition is increasingly determined by our capacity to handle such highly cohesive materials, and to exploit their novel physical, chemical and mechanical characteristics. Devising handling mechanisms and understanding nano particulate flows depends on formulating accurate mathematical models which reflect the correct underlying physics. This APF proposal will utilise advanced continuum mechanics to develop the correct underlying conceptual ideas to resolve fundamental nanomechanical particulate flows, which will lead to the next generation of engineering tools.
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