Desalination Options for Metropolitan Adelaide's Water Supply & Implications for Water Resource Allocation to Regional Communities. This project will present a proposal for water supply augmentation by desalination to alleviate rising salinity concerns and supply uncertainty of River Murray water supplies to metropolitan Adelaide in South Australia. It will investigate the feasibility of desalination options available and their consequences for regional agriculture and industry that rely on rive ....Desalination Options for Metropolitan Adelaide's Water Supply & Implications for Water Resource Allocation to Regional Communities. This project will present a proposal for water supply augmentation by desalination to alleviate rising salinity concerns and supply uncertainty of River Murray water supplies to metropolitan Adelaide in South Australia. It will investigate the feasibility of desalination options available and their consequences for regional agriculture and industry that rely on river water from metropolitan water supply pipelines for their economic survival. The project outcomes will have significant implications for government water policies and private and public sector water-infrastructure investment. It will be the first detailed study of large-scale municipal desalting costs under Australian conditions.Read moreRead less
Desalting reclaimed wastewater to safeguard Virginia's horticultural industries. Virginia is a major horticultural region of South Australia undergoing rapid expansion. Groundwater resources are depleted and reclaimed sewage effluent from Adelaide is required for irrigation. Unfortunately, the effluent is frequently too saline. Large-scale desalting is being considered. A pilot-scale plant will be built to evaluate suitable desalting processes (e.g. reverse osmosis) for reducing the effluent ....Desalting reclaimed wastewater to safeguard Virginia's horticultural industries. Virginia is a major horticultural region of South Australia undergoing rapid expansion. Groundwater resources are depleted and reclaimed sewage effluent from Adelaide is required for irrigation. Unfortunately, the effluent is frequently too saline. Large-scale desalting is being considered. A pilot-scale plant will be built to evaluate suitable desalting processes (e.g. reverse osmosis) for reducing the effluent's salt content. Original research will: (i) synthesize the best combination of technologies to produce effluent streams of varying salinity for matching different crop requirements; and (ii) optimise delivery and storage of effluent streams using new storage(s) and the region's multiple aquifer and surface storages.Read moreRead less
Production of Biodegradable Polyhydroxyalkanoate Polymers using Advanced Biological Wastewater Treatment Process Technology. The aim of this project is to develop a sustainable process for producing biodegradable polyhydroxyalkanoate (PHAs)polymers from an innovative aerobic-anaerobic biological wastewater treatment process, ?treating? high strength food industry effluent. These biopolymers offer enormous potential for use as renewable and biodegradable thermoplastics.
It is proposed to inve ....Production of Biodegradable Polyhydroxyalkanoate Polymers using Advanced Biological Wastewater Treatment Process Technology. The aim of this project is to develop a sustainable process for producing biodegradable polyhydroxyalkanoate (PHAs)polymers from an innovative aerobic-anaerobic biological wastewater treatment process, ?treating? high strength food industry effluent. These biopolymers offer enormous potential for use as renewable and biodegradable thermoplastics.
It is proposed to investigate two process configurations, namely the sequencing batch reactor and a continuous two step anaerobic-aerobic reaction system. These will be studied at bench-scale. The outcomes include:
1. Determination of the optimum microbial conditions and key growth
parameters for the production of PHA.
2. Optimisation of the process configuration, operating strategies
and operating conditions to maximise the
production of PHA.
3. Assessment of the influence of the feed composition (e.g. VFA)
on the PHA composition (PHB/PHV).
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Development and Modellling of Advanced Coagulation and Oxidation Processes. The success of this program will help place Australia at the forefront of water quality control and management research. It will address concerns with managing and treating waters of changing characteristics due to climate change. In addition to the socio benefits, project success will also impart economic benefits to the nation through (i) fabricating new hybrid coagulants, that are versatile with enhanced performance ....Development and Modellling of Advanced Coagulation and Oxidation Processes. The success of this program will help place Australia at the forefront of water quality control and management research. It will address concerns with managing and treating waters of changing characteristics due to climate change. In addition to the socio benefits, project success will also impart economic benefits to the nation through (i) fabricating new hybrid coagulants, that are versatile with enhanced performance for removing NOM, and possess antimicrobial properties (ii) developing a new energy efficient photocatalysis technology.The proposed research will expand the knowledge base in this area and increase Australia’s international profile as a global leader in developing cutting-edge cost effective water resource technologies.Read moreRead less
Multi-scale strategy to manage chloramine decay and nitrification in water distribution systems. The generation of knowledge and technologies in preventing chloramine decay would greatly benefit the Australian water industry. The success of the project would provide the highest possible quality of water, both economically and reliably, giving public assurances of microbiological compliance and safe drinking water.
Advanced environmental technologies for increasing coal seam permeability. This project aims to understand the physical/chemical mechanisms occurring when benign chemicals interact and dissolve minerals and coal surfaces in the natural fractures during the extraction of coal seam gas. Technologies for increasing the permeability of coal have become necessary for commercially viable coal seam gas (CSG) extraction in Australia. Currently available methods from the conventional gas industry, are pr ....Advanced environmental technologies for increasing coal seam permeability. This project aims to understand the physical/chemical mechanisms occurring when benign chemicals interact and dissolve minerals and coal surfaces in the natural fractures during the extraction of coal seam gas. Technologies for increasing the permeability of coal have become necessary for commercially viable coal seam gas (CSG) extraction in Australia. Currently available methods from the conventional gas industry, are problematic for coal, and fail to capitalise on coal’s existing fracture network. The intended project outcome is a range of new coal-specific technologies for enhancing permeability that avoid unwanted and irreversible damage to seams and protect the environment. Combined with reduced costs, these methods would benefit sustainable growth of Australia’s CSG industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989675
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Interface-specific facility for quantifying adsorption and structures at particulate interfaces. The facility will be used by the collaborating universities to investigate adsorption and interface properties with great precision, and to develop new and improved technologies for coal and mineral processing, saline water utilisation, water desalination, energy production and environment protection. In particular, the project will investigate innovative ways of using ion-interface interactions in ....Interface-specific facility for quantifying adsorption and structures at particulate interfaces. The facility will be used by the collaborating universities to investigate adsorption and interface properties with great precision, and to develop new and improved technologies for coal and mineral processing, saline water utilisation, water desalination, energy production and environment protection. In particular, the project will investigate innovative ways of using ion-interface interactions in saline water for cleaning coal and recovering value minerals by flotation, and for improving dissolved air flotation used in water treatment and desalination to produce drinking water. The project will further investigate novel ways of capturing CO2, storing natural gases and hydrogen, and tailoring nutrient nano-crystals for foliar delivery.Read moreRead less
Mitigation of silica nanoparticle scaling in water treatment. This project aims to develop strategies to mitigate silica scaling at coal seam gas (CSG) water treatment facilities. CSG is adsorbed to the surface of coal along fractures and cleats and released when pressure is reduced by removal of groundwater, which has chemistry specific to the region from which it is extracted. Desalination of produced water is severely impacted by mineral scaling on reverse osmosis membranes. This project will ....Mitigation of silica nanoparticle scaling in water treatment. This project aims to develop strategies to mitigate silica scaling at coal seam gas (CSG) water treatment facilities. CSG is adsorbed to the surface of coal along fractures and cleats and released when pressure is reduced by removal of groundwater, which has chemistry specific to the region from which it is extracted. Desalination of produced water is severely impacted by mineral scaling on reverse osmosis membranes. This project will consider silica and silica-rich nanoparticles in concert with cations and organics, with the aim of better managing cations so to facilitate nanoparticle lubrication. Project outcomes may include more productive use of assets, improved pre-treatment infrastructure to support reverse osmosis operation, and the environmental benefits of reduced chemical waste and increased water recovery.Read moreRead less
Catalytic Degardation of Emerging Microplastic Pollutants. This project aims to develop robust and low-cost nanocarbon hybrids and advanced remediation technology to address globally emerging microplastic contaminations. The project expects to boost innovations in development of novel magnetic nanomaterials, process of microplastic purification, and green catalysis. Expected outcomes of this project will include efficient strategies in materials fabrication and a cutting-edge nanotechnology. The ....Catalytic Degardation of Emerging Microplastic Pollutants. This project aims to develop robust and low-cost nanocarbon hybrids and advanced remediation technology to address globally emerging microplastic contaminations. The project expects to boost innovations in development of novel magnetic nanomaterials, process of microplastic purification, and green catalysis. Expected outcomes of this project will include efficient strategies in materials fabrication and a cutting-edge nanotechnology. The success of the project will underpin the scientific bases of carbocatalysis, provide significant benefits to the Australian industry and society for a sustainable future with clean water, and increase the leading capacity of Australia in fundamental research and frontier technology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100253
Funder
Australian Research Council
Funding Amount
$450,948.00
Summary
Functional carbon hybrids for green catalysis and clean water. This project aims to develop a family of structure-tailored, robust and metal-free carbon hybrids and environmental-benign processes for catalytic degradation of emerging microcontaminants in water. Innovations are expected in the design of reaction-oriented nanocarbons, new concept in atomic level carbocatalysis from computation and in-situ characterisation, advanced purification technology, and breakthroughs in material engineering ....Functional carbon hybrids for green catalysis and clean water. This project aims to develop a family of structure-tailored, robust and metal-free carbon hybrids and environmental-benign processes for catalytic degradation of emerging microcontaminants in water. Innovations are expected in the design of reaction-oriented nanocarbons, new concept in atomic level carbocatalysis from computation and in-situ characterisation, advanced purification technology, and breakthroughs in material engineering. The anticipated outcomes will be the scientific basis for functional nanomaterials, nanotechnology, and green remediation technologies. Success will provide significant benefits in securing a sustainable future for Australia, with clean water and strategies for advanced manufacturing in related areas. Read moreRead less