Novel hybrid silica membranes for desalination. This project aims to produce high flux, highly stable ceramic membranes for use in desalination. This will result in novel, low energy desalination processes, delivering potable water at a greatly reduced cost.
Biosolid flow, separation and activity in anaerobic lagoons. This project aims to develop a fundamental model of the complex, non-steady state flow behaviour in anaerobic lagoons. The project will develop new operating procedures and designs for large municipal, industrial and agricultural anaerobic lagoons. This will improve the efficiency of anaerobic digestion and reduce wastewater treatment costs, as well as increase renewable and sustainable biogas production. The intended outcome is a va ....Biosolid flow, separation and activity in anaerobic lagoons. This project aims to develop a fundamental model of the complex, non-steady state flow behaviour in anaerobic lagoons. The project will develop new operating procedures and designs for large municipal, industrial and agricultural anaerobic lagoons. This will improve the efficiency of anaerobic digestion and reduce wastewater treatment costs, as well as increase renewable and sustainable biogas production. The intended outcome is a validated 3D model that captures the physical and biological complexities of anaerobic lagoons. This will impact the design and operation of partner organisation lagoons, reducing capital and operating costs and improving biogas production.Read moreRead less
Efficient Pipeline Transport of Highly Concentrated Wastewater Sludge . This project aims to investigate the rheology and fluid mechanics of highly concentrated wastewater sludges and develop tools to support effective pipeline designs for wastewater treatment plants. The project expects to generate new knowledge about the complex flow of concentrated wastewater which will enable predictive models to support the design and optimization of pipeline transport systems. Expected outcomes of the proj ....Efficient Pipeline Transport of Highly Concentrated Wastewater Sludge . This project aims to investigate the rheology and fluid mechanics of highly concentrated wastewater sludges and develop tools to support effective pipeline designs for wastewater treatment plants. The project expects to generate new knowledge about the complex flow of concentrated wastewater which will enable predictive models to support the design and optimization of pipeline transport systems. Expected outcomes of the project include a new toolkit that will enable wastewater treatment plants to design and optimize both existing and future pipeline systems. This will support the Australian wastewater industry to plan for future growth, increase throughput and efficiency, reduce environmental pollutants, and capital and operating costs.Read moreRead less
Algal control using multi-functional, cold plasma activated microbubbles . Climate change is driving a proliferation of nuisance and harmful algal blooms in our water supply systems, which urgently require cost efficient and effective control strategies. Paradoxically, algal biotechnology is a growth industry with application in food, agriculture and energy; realising this potential requires state-of-the-art technology to optimise production, harvesting and extraction. The aim of this proposal i ....Algal control using multi-functional, cold plasma activated microbubbles . Climate change is driving a proliferation of nuisance and harmful algal blooms in our water supply systems, which urgently require cost efficient and effective control strategies. Paradoxically, algal biotechnology is a growth industry with application in food, agriculture and energy; realising this potential requires state-of-the-art technology to optimise production, harvesting and extraction. The aim of this proposal is to develop cutting edge technology that uses cold plasma activated microbubbles to control algal populations. We propose that by tuning the plasma composition, this technology could both selectively disrupt and destroy algal matter and enhance algal cell growth, benefiting both water and biotechnology industries. Read moreRead less
Engineered Inorganic Membranes for Novel Mineral Brine Processing. This project aims to synthesise a new generation of engineered hierarchical membranes for novel brine processing. The key concept of the research is the precise tailoring of pores of inorganic films, forming functional meso-structures for separating salts from water. Salt crystallises perpendicular to the surface of the membrane, whilst easily removed by air, a process that can be repeated many times leading to high production ra ....Engineered Inorganic Membranes for Novel Mineral Brine Processing. This project aims to synthesise a new generation of engineered hierarchical membranes for novel brine processing. The key concept of the research is the precise tailoring of pores of inorganic films, forming functional meso-structures for separating salts from water. Salt crystallises perpendicular to the surface of the membrane, whilst easily removed by air, a process that can be repeated many times leading to high production rates. The hierarchical membranes will be studied to elucidate the relationships between structure, composition, surface properties and transport phenomena. The outcomes should advance brine processing separation technologies for the mineral industry (lithium, potassium, and magnesium).Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100694
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Building resilience in wastewater infrastructure with self-healing bioconcrete. This project aims to develop a microbial self-healing bio-concrete to extend the service life of wastewater collection and treatment facilities. Water utilities worldwide struggle with asset management, because global warming and extreme weather age and corrode concrete infrastructure. This project will use microbially-induced calcium carbonate precipitation by bacteria to treat wastewater. The bacteria, added to bio ....Building resilience in wastewater infrastructure with self-healing bioconcrete. This project aims to develop a microbial self-healing bio-concrete to extend the service life of wastewater collection and treatment facilities. Water utilities worldwide struggle with asset management, because global warming and extreme weather age and corrode concrete infrastructure. This project will use microbially-induced calcium carbonate precipitation by bacteria to treat wastewater. The bacteria, added to bio-concrete, can fill cracks or reseal corroded areas by using organic substrates from wastewater to generate concrete, thus maintaining structural strength and preventing further damage. This project is expected to enhance the resilience and sustainability of wastewater infrastructure in ever more demanding environments.Read moreRead less
Ultrathin membranes of novel structures for highly efficient water reuse. This project aims to develop a new generation of reverse osmosis membranes to enable significantly more efficient water reuse. The project expects to generate new knowledge in the area of membrane technology and wastewater reclamation using innovative designs of membrane structures and new techniques for membrane synthesis. Expected outcomes of the project include the development of highly permeable and high selective reve ....Ultrathin membranes of novel structures for highly efficient water reuse. This project aims to develop a new generation of reverse osmosis membranes to enable significantly more efficient water reuse. The project expects to generate new knowledge in the area of membrane technology and wastewater reclamation using innovative designs of membrane structures and new techniques for membrane synthesis. Expected outcomes of the project include the development of highly permeable and high selective reverse osmosis membranes. This project should provide significant benefits to water reuse by greatly improving product water quality and dramatically reducing its energy consumption by over 50 per cent, which in turn addresses the challenges of water scarcity and water-energy nexus.Read moreRead less
Fast stimuli-responsive polymer hydrogels as a new class of draw agent for forward osmosis desalination. The ability to extract fresh water from saline water can be important in areas such as desalination and other industrial applications. In this project new materials will be developed to perform this operation at a much lower energy cost than similar processes, whilst also improving the purity of the separated water.