Analytics to predict anaerobic codigestion & downstream process performance. This project aims to develop management approaches to enable the use of anaerobic co-digestion — the conversion of organic wastes and wastewater sludge to biogas for electricity production. Anaerobic co-digestion has the potential to bring significant economic savings to water stakeholders and environmental benefits to communities. However, full-scale deployment faces fundamental challenges in terms of managing impacts ....Analytics to predict anaerobic codigestion & downstream process performance. This project aims to develop management approaches to enable the use of anaerobic co-digestion — the conversion of organic wastes and wastewater sludge to biogas for electricity production. Anaerobic co-digestion has the potential to bring significant economic savings to water stakeholders and environmental benefits to communities. However, full-scale deployment faces fundamental challenges in terms of managing impacts on downstream processes (e.g. odour, dewaterability, biogas quality, and nutrient build-up). The analytical framework and analytics tool to be developed in this project by an interdisciplinary team with expertise in process engineering, biochemistry, analytical chemistry and analytics, is expected to enable water stakeholders to cost-effectively manage these impacts and thus realise the benefits of co-digestion.Read moreRead less
Impact of Fouling on Retention of Contaminants in Electrodialysis for Brackish Water and Wastewater Applications. Water desalination and water recycling are both of utmost importance in the current global water crisis. Reverse osmosis is a commonly used process in both areas but this process has two main limitations (1) it is limited in water recovery by the concentration of salts, and (2) it produces a relatively large amount of concentrates that require disposal. Using electrodialysis to treat ....Impact of Fouling on Retention of Contaminants in Electrodialysis for Brackish Water and Wastewater Applications. Water desalination and water recycling are both of utmost importance in the current global water crisis. Reverse osmosis is a commonly used process in both areas but this process has two main limitations (1) it is limited in water recovery by the concentration of salts, and (2) it produces a relatively large amount of concentrates that require disposal. Using electrodialysis to treat such concentrates will decrease the salinity problem caused by disposal and also increase the water efficiency of the treatment process. In this research project the potential performance limitations fouling and micropollutant removal will be investigated and hence the performance improved.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100970
Funder
Australian Research Council
Funding Amount
$426,966.00
Summary
A novel technology for enhancing resource recovery from wastewater. This DECRA project aims to improve the performance and economics of wastewater management, by developing an innovative technology and the underpinning science that will enhance renewable energy production and nutrient recovery from sludge. This technology is based on the enhancement of resource recovery from anaerobic digestion using waste iron scraps that can be acquired from the waste of metal industry. The intended outcome of ....A novel technology for enhancing resource recovery from wastewater. This DECRA project aims to improve the performance and economics of wastewater management, by developing an innovative technology and the underpinning science that will enhance renewable energy production and nutrient recovery from sludge. This technology is based on the enhancement of resource recovery from anaerobic digestion using waste iron scraps that can be acquired from the waste of metal industry. The intended outcome of the project will substantially increase the profit and reduce the environmental burden of waste treatment, supporting Australia in the transition to a low carbon economy and a secure resource future. This project will produce significant economic, environmental and social benefits to water utilities.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100959
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Adsorptive removal of mercury from natural gas by carbonaceous material. The project aims to improve understanding of the adsorption mechanism of mercury removal from natural gas with porous carbon materials, by applying novel molecular simulation tools. An increasing number of Australian gas reservoirs have been found to contain higher levels of mercury than the specified safety, environment and product requirements. Although most of the current methods of mercury removal are based on adsorptio ....Adsorptive removal of mercury from natural gas by carbonaceous material. The project aims to improve understanding of the adsorption mechanism of mercury removal from natural gas with porous carbon materials, by applying novel molecular simulation tools. An increasing number of Australian gas reservoirs have been found to contain higher levels of mercury than the specified safety, environment and product requirements. Although most of the current methods of mercury removal are based on adsorption technology, its development and use to full potential has been impeded by a lack of understanding. This project aims to investigate the fundamental mechanism of mercury removal from natural gas with adsorption methods at the molecular level. The project is intended to pave the way for optimal design of mercury removal systems.Read moreRead less
Sustainable Water Reuse and Resource Recovery through Cost-Effective BNR. The recycling of treated wastewater effluents is needed to achieve water security, where very low nitrogen (N) and phosphorus (P) levels must be achieved for wastewater to be effectively recycled. This research investigates a more sustainable and cost-effective N&P removal process from wastewater, benefiting the environment and improving the viability of wastewater recycling. Phosphorus is a limited resource worldwide and ....Sustainable Water Reuse and Resource Recovery through Cost-Effective BNR. The recycling of treated wastewater effluents is needed to achieve water security, where very low nitrogen (N) and phosphorus (P) levels must be achieved for wastewater to be effectively recycled. This research investigates a more sustainable and cost-effective N&P removal process from wastewater, benefiting the environment and improving the viability of wastewater recycling. Phosphorus is a limited resource worldwide and will be effectively recovered in the process to be used as a fertiliser. This project develops wastewater treatment process tools, solutions and management strategies that addresses the current challenges of how optimal nutrient removal and recovery from wastewater is achieved, enabling water recycling and saving costs.Read moreRead less
Integration of Life Cycle Analysis, EnternE, and Economic Models to Sustainable Regional Development. This project involves the development of a novel decision-making framework to support the transition to sustainability within regions. The approach is based on integrating the methodologies of Life Cycle Analysis, externality costing and traditional economic analysis to assess the tradeoffs between economic, environmental and social outcomes. The integration of these techniques will allow the re ....Integration of Life Cycle Analysis, EnternE, and Economic Models to Sustainable Regional Development. This project involves the development of a novel decision-making framework to support the transition to sustainability within regions. The approach is based on integrating the methodologies of Life Cycle Analysis, externality costing and traditional economic analysis to assess the tradeoffs between economic, environmental and social outcomes. The integration of these techniques will allow the relative magnitude of positive and negative impacts of development decisions to be reported as an economic unit. This will allow the tradeoffs that occur between economic, environmental and social considerations to be quantified and the sustainability of a development or planning scenario to be assessed.Read moreRead less
Combating the spread of antibiotic resistance in urban water systems. This projects aims to investigate the occurrence, diversity, and transformation of antibiotic resistant genes in the entire urban water cycle. Using the latest metagenomic and analytical tools, this project will enhance our knowledge on fate and transfer mechanisms of antibiotic resistance genes in the urban water cycle. Based on this understanding, an expected outcome of the project is the development of innovative technologi ....Combating the spread of antibiotic resistance in urban water systems. This projects aims to investigate the occurrence, diversity, and transformation of antibiotic resistant genes in the entire urban water cycle. Using the latest metagenomic and analytical tools, this project will enhance our knowledge on fate and transfer mechanisms of antibiotic resistance genes in the urban water cycle. Based on this understanding, an expected outcome of the project is the development of innovative technologies for efficient reduction of antibiotic resistance genes to have future applications for environmental, human health and economic benefits for Australia.Read moreRead less
Optimising nanofiltration and reverse osmosis filtration processes for water recycling: effects of fouling and chemical cleaning on trace contaminant removal. In Australia, water recycling is considered a principal measure to manage the current ongoing water shortage and to better protect the environment. Membrane filtration processes play important roles in the treatment of reclaimed municipal wastewater. However, there is very limited knowledge regarding the reliability of such processes in re ....Optimising nanofiltration and reverse osmosis filtration processes for water recycling: effects of fouling and chemical cleaning on trace contaminant removal. In Australia, water recycling is considered a principal measure to manage the current ongoing water shortage and to better protect the environment. Membrane filtration processes play important roles in the treatment of reclaimed municipal wastewater. However, there is very limited knowledge regarding the reliability of such processes in removing trace contaminants from recycled water, which may result in unintended health consequences. This research will lead to a comprehensive understanding of the removal process of such contaminants by membrane filtration. Consequently, the likely avenue of risk can be eliminated and the treatment process can be optimised to achieve economic savings and environmental protection.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
Engineering defect-intensive ozonation catalysts to degrade micropollutants. This project aims to engineer unique particles containing defect-intensive surfaces which are designed to accelerate the catalytic ozonation of waters contaminated with pharmaceuticals and other recalcitrant pollutants. This will enable timely treatment of industrial waste water as well as sewerage treatment plant effluents using simple and cheap catalyst materials. Wet- and flame-based particle fabrication technologies ....Engineering defect-intensive ozonation catalysts to degrade micropollutants. This project aims to engineer unique particles containing defect-intensive surfaces which are designed to accelerate the catalytic ozonation of waters contaminated with pharmaceuticals and other recalcitrant pollutants. This will enable timely treatment of industrial waste water as well as sewerage treatment plant effluents using simple and cheap catalyst materials. Wet- and flame-based particle fabrication technologies paired with unique post-synthesis treatment strategies, including either a coupled hydrogenation-illumination approach or plasma exposure, will be implemented for defect manipulation so as to produce new cheaper, stable, and higher-performing catalysts for activating ozone to treat water containing pharmaceutical and endocrine disrupting micro-pollutants under different process conditions.Read moreRead less