Causes of and Cures for Microbiological Foams in Activated Sludge Wastewater Treatment Plants. Little is known of the true diversity of the bacteria causing foaming in activated sludge systems, or why and how they cause these foams. This application seeks funds for an interdisciplinary approach to address these issues, involving input from microbiologists and surface chemists and physicists. Molecular techniques will be used to determine precisely the foaming bacterial communities and their phys ....Causes of and Cures for Microbiological Foams in Activated Sludge Wastewater Treatment Plants. Little is known of the true diversity of the bacteria causing foaming in activated sludge systems, or why and how they cause these foams. This application seeks funds for an interdisciplinary approach to address these issues, involving input from microbiologists and surface chemists and physicists. Molecular techniques will be used to determine precisely the foaming bacterial communities and their physiology, while their surface chemistry and organisation will be studied to understand the mechanisms involved in foaming with the intention of developing control strategies for this global problem suitable for large scale application.Read moreRead less
Development of Nanostructured TiO2 Electrodes for Photoelectrocatalytic Degradation of Organic and Microbial Pollutants in Wastewater. Australia is one of the driest continents and re-use of water/wastewater has been an urgent issue. Photoelectrocatalytic oxidation processes based on nanostructured TiO2 electrode are able to mineralize common aquatic organic and microbial pollutants. The proposed technology has the advantages of strong oxidation power and cheap production cost, and it is chemi ....Development of Nanostructured TiO2 Electrodes for Photoelectrocatalytic Degradation of Organic and Microbial Pollutants in Wastewater. Australia is one of the driest continents and re-use of water/wastewater has been an urgent issue. Photoelectrocatalytic oxidation processes based on nanostructured TiO2 electrode are able to mineralize common aquatic organic and microbial pollutants. The proposed technology has the advantages of strong oxidation power and cheap production cost, and it is chemically stable, robust under UV illumination, and most importantly, environmentally friendly. The success of the project can place Australia in a leading position of developing cutting-edge TiO2 nano-material-based photoelectrochemical technologies for environmental wastewater treatment and drinking water disinfection. Read moreRead less
Multifunctional mixed matrix membranes incorporating aligned carbon nanotubes. The pressure on water supplies in Australia will only increase in coming years meaning that effective and cheap means of recycling water must be found. By developing a carbon nanotube-based water filtration system, we intend to promote the growth of Australia's world-class reputation in water remediation. The technological outcomes from this research will lead to direct economic and environmental benefits for the comm ....Multifunctional mixed matrix membranes incorporating aligned carbon nanotubes. The pressure on water supplies in Australia will only increase in coming years meaning that effective and cheap means of recycling water must be found. By developing a carbon nanotube-based water filtration system, we intend to promote the growth of Australia's world-class reputation in water remediation. The technological outcomes from this research will lead to direct economic and environmental benefits for the community and offer commercial opportunities for industry. Training research scientists of the future forms an integral part of our program as it is crucial to maintain a critical mass in this potentially forthcoming water based economy.
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Towards a Molecular-Scale Understanding of Sorption of Organic Pollutants to Soil. The toxicity, mobility and persistence of organic pollutants in soils are in large part controlled by their sorption to soil organic matter. The chemical nature or quality of the organic matter affects not only the amount of chemical sorbed, but also the reversibility of sorption and the rate of sorption and desorption. Until now, only bulk measures of soil organic matter chemistry have been considered in sorption ....Towards a Molecular-Scale Understanding of Sorption of Organic Pollutants to Soil. The toxicity, mobility and persistence of organic pollutants in soils are in large part controlled by their sorption to soil organic matter. The chemical nature or quality of the organic matter affects not only the amount of chemical sorbed, but also the reversibility of sorption and the rate of sorption and desorption. Until now, only bulk measures of soil organic matter chemistry have been considered in sorption studies. This project introduces novel spectroscopic techniques that for the first time identify the chemical environment of sorbed molecules at the molecular scale. This will enable better prediction of pollutant transport and degradation.Read moreRead less
Effect of cane sugar juice composition on scaling rate and scale composition in sugar mills. The Australia sugar industry produces 1100 GWh of renewable electricity annually, abating ~1.1 M tonnes of CO2-equivalent of greenhouse gases. This can be increased if the juice evaporation performance, which largely determines the energy efficiency of the sugar factory, can be improved through reduced fouling of evaporators. This project will investigate the effect of juice composition on fouling of sug ....Effect of cane sugar juice composition on scaling rate and scale composition in sugar mills. The Australia sugar industry produces 1100 GWh of renewable electricity annually, abating ~1.1 M tonnes of CO2-equivalent of greenhouse gases. This can be increased if the juice evaporation performance, which largely determines the energy efficiency of the sugar factory, can be improved through reduced fouling of evaporators. This project will investigate the effect of juice composition on fouling of sugar factory evaporators so that a model to predict scale type and scale propensity can be developed. This will enable the development of better scale control strategies, resulting in reduced energy usage and reduced usage of the hazardous and polluting chemicals required to remove scale.Read moreRead less
Lowering membrane fouling by matching pre-treatment to membrane type. Delivery of potable and recycled water to communities and industry increasingly uses membrane treatment to ensure high standards of water quality, particularly as water scarcity leads to the use of poor quality water sources. Fouling of membranes occurs as water is treated, adding expense and complexity to the process. Reducing fouling will lower the cost of water treatment and improve the economics of treating water in smal ....Lowering membrane fouling by matching pre-treatment to membrane type. Delivery of potable and recycled water to communities and industry increasingly uses membrane treatment to ensure high standards of water quality, particularly as water scarcity leads to the use of poor quality water sources. Fouling of membranes occurs as water is treated, adding expense and complexity to the process. Reducing fouling will lower the cost of water treatment and improve the economics of treating water in smaller systems at source. This will enable greater reliability of localised treatment, which will reduce pumping requirements and decrease both cost and carbon emissions. Read moreRead less
Impact of recycled and low quality process water on sustainable mineral processing practices. Water is in short supply and needs to be considered as a 'key reagent'. The quality of this reagent can vary widely. For a sustainable mineral processing practice, the use of recycled or low quality/saline process water will be essential for a plant to operate in the future. The major benefit is recognition that significant recycle of process water for flotation is achievable if simple water quality con ....Impact of recycled and low quality process water on sustainable mineral processing practices. Water is in short supply and needs to be considered as a 'key reagent'. The quality of this reagent can vary widely. For a sustainable mineral processing practice, the use of recycled or low quality/saline process water will be essential for a plant to operate in the future. The major benefit is recognition that significant recycle of process water for flotation is achievable if simple water quality control and management practices are implemented. In addition, a better understanding and control of water quality in recycled/saline process water may lead to improved flotation stability and performance, and reduced reagent consumption.Read moreRead less
Composite Mesoporous Solids of TiO2 Nano-Crystals and Silicate as Photo-catalysts for Degradation of Organic Contaminants in Water. TiO2 photo-catalysis is a promising advanced technique for breaking down organic contaminants and bacteria in water and air. This project will develop a novel class of photo-catalysts, the composite meosporous compounds of anatase and layered clay, by combining templated synthesis and pillaring techniques. They will exhibit a high photo-catalytic efficiency with sup ....Composite Mesoporous Solids of TiO2 Nano-Crystals and Silicate as Photo-catalysts for Degradation of Organic Contaminants in Water. TiO2 photo-catalysis is a promising advanced technique for breaking down organic contaminants and bacteria in water and air. This project will develop a novel class of photo-catalysts, the composite meosporous compounds of anatase and layered clay, by combining templated synthesis and pillaring techniques. They will exhibit a high photo-catalytic efficiency with superior properties for practical operations because of the framework of large porosity arising from the arrangement of discrete anatase nano-particles within the silicate layers. The project involves mostly fundamental research into material synthesis, colloid and surface chemistry and photo-catalysis, and aims to develop advanced techniques for water treatment.Read moreRead less
Nanostructures of Titanium Dioxide and Titanates by Wet-chemistry. One-dimensional (1D) nanoparticulates of titanium dioxide (TiO2) and titanate synthesized by wet-chemistry approaches are new advanced materials of unusual properties. This project will investigate the formation and phase transition mechanism of these 1D particulates by various techniques. With such knowledge, we can effectively control the morphology on a scale of nanometers, and tailor the energy gap of these materials. This wi ....Nanostructures of Titanium Dioxide and Titanates by Wet-chemistry. One-dimensional (1D) nanoparticulates of titanium dioxide (TiO2) and titanate synthesized by wet-chemistry approaches are new advanced materials of unusual properties. This project will investigate the formation and phase transition mechanism of these 1D particulates by various techniques. With such knowledge, we can effectively control the morphology on a scale of nanometers, and tailor the energy gap of these materials. This will significantly influence the photosemiconductive photocatalytic and lithium ions insertion behaviours of the particles so that advanced materials for solar energy conversion, photocatalysts for decomposing organic pollutants in environment, eletrode materials of lithium batteries can be developed.Read moreRead less
Efficient One-Dimensional Photocatalysts from Titanate Nanofibres and Nanotubes. This project will deliver important fundamental knowledge for the development of high-value products of titania, and thus will contribute directly to the priority goal of transforming the existing titania industry through value adding and export on the international market. This research will lead to new industries and will create employment opportunities for Australians. It will also serve to train young scientists ....Efficient One-Dimensional Photocatalysts from Titanate Nanofibres and Nanotubes. This project will deliver important fundamental knowledge for the development of high-value products of titania, and thus will contribute directly to the priority goal of transforming the existing titania industry through value adding and export on the international market. This research will lead to new industries and will create employment opportunities for Australians. It will also serve to train young scientists with a real appreciation of materials research and engineering, contributing to the overall competitiveness and productivity of Australian R&D. This project would lead to advances in important fields of clean energy, environment remediation and advanced materials processing in Australia.Read moreRead less