Sustainable Hydrogen Production from Used Water. The project aims to address the pressing challenge of water scarcity in hydrogen production by developing an innovative approach of using used water as the feed for water electrolysis. The project will result in an in-depth understanding of the impacts of water impurities in used water on the performance and durability of water electrolysers, and develop guidelines for the design of highly durable water electrolysers and the operation and upgrade ....Sustainable Hydrogen Production from Used Water. The project aims to address the pressing challenge of water scarcity in hydrogen production by developing an innovative approach of using used water as the feed for water electrolysis. The project will result in an in-depth understanding of the impacts of water impurities in used water on the performance and durability of water electrolysers, and develop guidelines for the design of highly durable water electrolysers and the operation and upgrade of existing wastewater treatment plants. The project will advance the practical applications of water electrolysis for scalable and sustainable hydrogen production and help Australia secure a leading position in the global emerging hydrogen economy.Read moreRead less
Scalable and Applicable Nanostructured Adsorbents for Arsenic Removal with High Performance. Arsenic contamination in groundwater and drinking water affects over 100 million people worldwide and causes severe health problems. This project aims to use a recently patented technology to develop a new generation of adsorbents with controlled nanostructure and morphology for arsenic removal. The novel low-cost adsorbents are expected to have superior performance for the treatment of water containing ....Scalable and Applicable Nanostructured Adsorbents for Arsenic Removal with High Performance. Arsenic contamination in groundwater and drinking water affects over 100 million people worldwide and causes severe health problems. This project aims to use a recently patented technology to develop a new generation of adsorbents with controlled nanostructure and morphology for arsenic removal. The novel low-cost adsorbents are expected to have superior performance for the treatment of water containing arsenic at both high and low concentrations. The engineered products will be tested in high-throughput wastewater treatment in pharmaceutical factories and as a household drinking water treatment device. This project aims to bring economic and social benefits to Australian industry and improve the quality of life for people all over the world.Read moreRead less
All-solid-state Z-scheme photocatalysts for water treatment. The project aims to develop high-performance Z-scheme photocatalysts by using two-dimensional (2D) semiconductors as building blocks for low-cost, highly-efficient pathogen inactivation and emerging pollutant degradation in stormwater treatment. The project expects to generate new fundamental knowledge in the area of photocatalyst design and Z-scheme photocatalytic system, and advance the application of photocatalytic oxidation in wate ....All-solid-state Z-scheme photocatalysts for water treatment. The project aims to develop high-performance Z-scheme photocatalysts by using two-dimensional (2D) semiconductors as building blocks for low-cost, highly-efficient pathogen inactivation and emerging pollutant degradation in stormwater treatment. The project expects to generate new fundamental knowledge in the area of photocatalyst design and Z-scheme photocatalytic system, and advance the application of photocatalytic oxidation in water treatment. The expected outcomes of the project include novel 2D Z-scheme photocatalysts and enhanced capacity in stormwater management.Read moreRead less
Improving anti-salt crystallisation for solar-steam desalination. This project aims to solve a critical issue of solar-steam desalination by fundamental research. The solar-steam desalination technology offers an ideal strategy to utilize solar light as the energy source for desalination and water purification to produce affordable clean water. Photothermal materials play a key role in the desalination system to convert sunlight to heat and subsequently evaporate the saline water to generate ste ....Improving anti-salt crystallisation for solar-steam desalination. This project aims to solve a critical issue of solar-steam desalination by fundamental research. The solar-steam desalination technology offers an ideal strategy to utilize solar light as the energy source for desalination and water purification to produce affordable clean water. Photothermal materials play a key role in the desalination system to convert sunlight to heat and subsequently evaporate the saline water to generate steam as clean water. However, salt crystallization on the photothermal material surfaces severely limits the performance of the materials and clean water production. Solving this problem could accelerate the commercialisation and application of this technology, which will benefit millions of people worldwide.Read moreRead less
Designing plasmon-enhanced photocatalysts for solar-driven water pollutant removal. The outcomes of this program will lead to a new class of composite photocatalysts for efficient water purification using sunlight. Such technology will speed up the transition of Australian environmental and energy industries from a fossil fuel economy to renewable energy economy.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100149
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Spectroscopic imaging for materials, minerals and life sciences. The spectroscopic imaging equipment highlighted in this proposal will produce a number of outcomes of national benefit. First, it will elevate the impact of research in materials, minerals, and life sciences in Australia, all of which are key areas for the national economy and community. Second, the equipment will be integral to the teaching and research nexus and experiential learning facility for a new wave of materials science ....Spectroscopic imaging for materials, minerals and life sciences. The spectroscopic imaging equipment highlighted in this proposal will produce a number of outcomes of national benefit. First, it will elevate the impact of research in materials, minerals, and life sciences in Australia, all of which are key areas for the national economy and community. Second, the equipment will be integral to the teaching and research nexus and experiential learning facility for a new wave of materials science and engineering students to be educated at UniSA in the EIF-funded M2 building at Mawson Lakes. Finally, the anticipated outcomes of the research to be supported are significant and relate clearly to a number of National Research Priorities.Read moreRead less
Development of Solar-induced, Dark-active Photocatalytic Membranes for Water Disinfection. Stormwater is one of the last freshwater resources that has not been utilised to its full potential. However, large amount of faecal pathogens in stormwater limit its harvesting practice.This project aims at addressing this significant problem by developing the next generation of photocatalytic membranes for stormwater disinfection. The proposed membranes not only are passive water treatment technology whi ....Development of Solar-induced, Dark-active Photocatalytic Membranes for Water Disinfection. Stormwater is one of the last freshwater resources that has not been utilised to its full potential. However, large amount of faecal pathogens in stormwater limit its harvesting practice.This project aims at addressing this significant problem by developing the next generation of photocatalytic membranes for stormwater disinfection. The proposed membranes not only are passive water treatment technology which only utilises solar energy, but also are operated regardless of weather, even at night. The results will provide new insights on development of future water treatment technologies. This project will also raise Australia’s credibility and competitiveness in the water and membrane industries.Read moreRead less
Advanced three-dimensional fibrous structures for vascular graft applications. This project will combine advanced three-dimensional fabric structures, surface functionalisation and haemodynamic modelling to tackle critical issues in the design and manufacture of vascular graft materials. It will lead to the next generation of vascular grafts with much enhanced structural and biomedical performance.
Discovery Early Career Researcher Award - Grant ID: DE120102451
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Spatial control of nanoporous materials for microfabrication. Treatment of numerous medical conditions will be revolutionised by biomedical devices that can deliver or remove selected molecules in precise locations (for example oxygenation of tissues, release of antitumor agents, toxin neutralisation). New lithographic protocols will be developed to enable the use of nanoporous filters directly for such purposes.