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Contribution of Comammox Process to Sustainable Wastewater Treatment. This project aims to understand the versatility, activity and physiological features of comammox bacteria, the newly-discovered complete nitrifiers, in Australian wastewater treatment systems, and to model and evaluate their contributions to biological nitrogen removal process. Nitrogen transformations are crucial microbial processes in the wastewater treatment ecosystems, with nitrification largely responsible for ammonium ox ....Contribution of Comammox Process to Sustainable Wastewater Treatment. This project aims to understand the versatility, activity and physiological features of comammox bacteria, the newly-discovered complete nitrifiers, in Australian wastewater treatment systems, and to model and evaluate their contributions to biological nitrogen removal process. Nitrogen transformations are crucial microbial processes in the wastewater treatment ecosystems, with nitrification largely responsible for ammonium oxidation but comammox previously overlooked. The expected outcomes will develop new knowledge on the comammox process and provide novel insight and technological solution to refine strategies to manipulate nitrification processes for achieving improved biological nitrogen removal and sustainable wastewater management.Read moreRead less
In-situ electrochemical generation of caustic and oxygen from sewage for emission control in sewers. This project aims to deliver an innovative technology that controls the emission of notorious compounds from sewer networks using chemicals directly produced from sewage, with electricity being the input. Compared to existing methods, this technology provides a much safer and more environmentally friendly solution, at less than 50 per cent of the cost.
Treatment of secondary sludge using free nitrous acid to enhance performance and economics of a wastewater treatment plant. This project will deliver a new process that utilises a by-product of wastewater treatment to reduce the environmental and financial costs of wastewater treatment. The project will significantly reduce waste materials discharged from wastewater treatment plants and enhance bioenergy recovery from wastewater, in addition to improving effluent quality.
Toxic metal removal from wastewater sludge. This project aims to efficiently remove toxic metals from wastewater sludge. Sludge management is a problem for water utilities, incurring substantial costs. Land application of wastewater sludge is a sustainable way of sludge management, but toxic metals hinder its long-term repeated application. The project’s chemical-free and energy-positive technology is based on the treatment of wastewater sludge using acidified nitrite. The outcomes will help wat ....Toxic metal removal from wastewater sludge. This project aims to efficiently remove toxic metals from wastewater sludge. Sludge management is a problem for water utilities, incurring substantial costs. Land application of wastewater sludge is a sustainable way of sludge management, but toxic metals hinder its long-term repeated application. The project’s chemical-free and energy-positive technology is based on the treatment of wastewater sludge using acidified nitrite. The outcomes will help water utilities to sustainably manage sludge and could bring large economic, environmental and social benefits to the water utilities.Read moreRead less
The application of inverse methods for resolving velocity, density and mixing fields in lakes and estuaries. The two techniques to be developed and tested here will allow the measurement of the 3D density and velocity fields in lakes and estuaries using only simple instruments and with minimum lake obstruction. Coupled with a Real Time Management System, these techniques can be used to validate numerical models and to simulate scenarios, such as future flood events, which have the potential fo ....The application of inverse methods for resolving velocity, density and mixing fields in lakes and estuaries. The two techniques to be developed and tested here will allow the measurement of the 3D density and velocity fields in lakes and estuaries using only simple instruments and with minimum lake obstruction. Coupled with a Real Time Management System, these techniques can be used to validate numerical models and to simulate scenarios, such as future flood events, which have the potential for contamination of water quality. The output from these simulations is then used, again in real time, to evaluate the new Index of Sustainable Functionality of the water body. When augmented with the results from this research we would have a tool that would help manage lakes and reservoirs to optimize the water quality, while maintaining the supply.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL170100086
Funder
Australian Research Council
Funding Amount
$2,924,858.00
Summary
Methane bioconversion to liquid chemicals. This project aims to develop a suite of leading-edge biotechnology solutions to enable the cost-effective production of liquid chemicals from biogas. This will create a much stronger economic driver for biogas production from organic wastes, by significantly increasing the value of biogas compared to its current use for power generation. With a multi-disciplinary approach, the project will substantially advance the fundamental science in the exciting an ....Methane bioconversion to liquid chemicals. This project aims to develop a suite of leading-edge biotechnology solutions to enable the cost-effective production of liquid chemicals from biogas. This will create a much stronger economic driver for biogas production from organic wastes, by significantly increasing the value of biogas compared to its current use for power generation. With a multi-disciplinary approach, the project will substantially advance the fundamental science in the exciting and highly valuable area of anaerobic microbial conversion of methane, the least understood process in the global carbon cycle. This transformational research has a strong potential to create a new biotechnology sector producing high-value chemicals from methane, and will propel Australia to the forefront of sustainable resources research.Read moreRead less
Simultaneous dissolved methane and nitrogen removal. Direct anaerobic treatment of wastewater converts majority of organic matters in wastewater to methane, an energy source. However, up to 50% of the methane produced stays dissolved in wastewater. Its subsequent stripping to atmosphere in aerobic treatment not only causes significant loss of energy but also emission of a potent greenhouse gas. This project aims to develop a technology that not only avoids methane stripping but also enables its ....Simultaneous dissolved methane and nitrogen removal. Direct anaerobic treatment of wastewater converts majority of organic matters in wastewater to methane, an energy source. However, up to 50% of the methane produced stays dissolved in wastewater. Its subsequent stripping to atmosphere in aerobic treatment not only causes significant loss of energy but also emission of a potent greenhouse gas. This project aims to develop a technology that not only avoids methane stripping but also enables its beneficial use to enhance nitrogen removal, which is otherwise typically unsatisfactory due to the lack of organic carbon to support denitrification. The project will provide strong support to the Australian water industry in their endeavour to achieve energy- and carbon-neutral wastewater services.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100667
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Removing a Key Barrier for Autotrophic Nitrogen Removal from Wastewater. This project aims to develop new technology to enable stable autotrophic nitrogen removal from domestic wastewater. The technology selectively suppresses the growth of nitrite-oxidising bacteria using a by-product of wastewater treatment – free nitrous acid. Maximising energy recovery from wastewater and providing greenhouse gas neutral water services have been the targets of water utilities in Australia and worldwide. The ....Removing a Key Barrier for Autotrophic Nitrogen Removal from Wastewater. This project aims to develop new technology to enable stable autotrophic nitrogen removal from domestic wastewater. The technology selectively suppresses the growth of nitrite-oxidising bacteria using a by-product of wastewater treatment – free nitrous acid. Maximising energy recovery from wastewater and providing greenhouse gas neutral water services have been the targets of water utilities in Australia and worldwide. The project will potentially change wastewater management and bring economic, environmental and social benefits to water utilities.Read moreRead less
Fungal Biomass Protein, a Bioproduct Derived from a Treatment Process of Winery Waste Streams. The Australian wine industry produces a substantial quantity of wastewater containing high levels of organic materials that are both highly polluting and costly to treat. This research aims to develop a biotechnological treatment process integrated with fungal biomass protein (FBP) production from the winery waste streams. The outcomes of this project are i) the production of fungal biomass for use as ....Fungal Biomass Protein, a Bioproduct Derived from a Treatment Process of Winery Waste Streams. The Australian wine industry produces a substantial quantity of wastewater containing high levels of organic materials that are both highly polluting and costly to treat. This research aims to develop a biotechnological treatment process integrated with fungal biomass protein (FBP) production from the winery waste streams. The outcomes of this project are i) the production of fungal biomass for use as a protein-rich animal feed; ii); the treatment of waste water to allow reuse for farm irrigation; and iii) reduced pollution of watercourses. The research will develop a novel technology that is environmentally friendly and adds value to the Australian winery industry via pollution reduction and FBP production.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101401
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A novel autotrophic biological nitrogen removal process driven by ammonia-oxidising archaea and anammox bacteria. This project will provide fundamental support to the development of more sustainable nitrogen removal processes. This would bring considerable benefits to the Australian wastewater industry and could potentially influence the way that biological nutrient removal plants are designed and operated.