Discovery Early Career Researcher Award - Grant ID: DE170101069
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Two-dimensional inorganic nanostructures for hydrogen evolution reaction. This project aims to synthesise highly active electrochemical catalysts of two-dimensional (2D) inorganic nanostructure for hydrogen evolution reaction (HER). The electrocatalysis of water to produce hydrogen gas could generate clean energy, but the platinum catalyst’s cost and low activity make it impractical. This project will develop 2D inorganic nanosheets with tuneable pores and electronic band structures, hybridised ....Two-dimensional inorganic nanostructures for hydrogen evolution reaction. This project aims to synthesise highly active electrochemical catalysts of two-dimensional (2D) inorganic nanostructure for hydrogen evolution reaction (HER). The electrocatalysis of water to produce hydrogen gas could generate clean energy, but the platinum catalyst’s cost and low activity make it impractical. This project will develop 2D inorganic nanosheets with tuneable pores and electronic band structures, hybridised with organic and/or inorganic semiconductor nanomaterials for HER, and use density functional theory calculation to investigate these hybridised nanosheets’ mechanisms for HER. These highly efficient and low-cost catalysts are expected to generate clean energy and create opportunities for Australian industries.Read moreRead less
Unravelling mechanisms in plasma growth of polymers. Surface engineering broadens the breadth of applications for many materials, and enhances the performance and value of current and emerging technologies. Surface engineering is particularly important to maintaining the competitiveness of manufacturing in developed economies such as Australia, that can not compete on a cost basis with emerging economies. Plasma coating replaces (alternative) environmentally-questionable surface treatments. This ....Unravelling mechanisms in plasma growth of polymers. Surface engineering broadens the breadth of applications for many materials, and enhances the performance and value of current and emerging technologies. Surface engineering is particularly important to maintaining the competitiveness of manufacturing in developed economies such as Australia, that can not compete on a cost basis with emerging economies. Plasma coating replaces (alternative) environmentally-questionable surface treatments. This project enhances Australian competitiveness; it cuts across industrial sectors and will deliver the new knowledge required to enhance material/technology functionality/performance. A PhD student will receive a multi-disciplinary training in a frontier technology and advanced analytical tools.Read moreRead less
Cluster hardening of metastable steel alloys produced by thin strip casting. The goal of this project is to generate sufficient knowledge to apply strip casting to a wider range of steel grades and reduce the global energy cost of steel sheet production. Over 1 billion tonnes of steel is produced every year. Direct strip casting is an emerging green technology that reduces the energy required to process liquid steel into thin sheet product by up to 90 per cent. This study plans to use advanced a ....Cluster hardening of metastable steel alloys produced by thin strip casting. The goal of this project is to generate sufficient knowledge to apply strip casting to a wider range of steel grades and reduce the global energy cost of steel sheet production. Over 1 billion tonnes of steel is produced every year. Direct strip casting is an emerging green technology that reduces the energy required to process liquid steel into thin sheet product by up to 90 per cent. This study plans to use advanced atomic-scale characterisation techniques such as atom probe tomography and high-resolution electron microscopy to understand the non-equilibrium microstructures that develop as a result of the extremely rapid cooling rates experienced during strip casting.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100034
Funder
Australian Research Council
Funding Amount
$675,000.00
Summary
Investigating materials on the atomic scale using 3-dimensional atom probe tomography. A facility capable of examining the position of individual atoms inside a material will be established to serve the Australian research community. This information will be used to design engineering alloys with improved strength, biocompatibility and reduced environmental footprints. It will also be used to characterise alloys produced by new green technologies.
Preventing biological growth – a new generation anti-biofouling coatings. The project aims to improve anti-biofouling technology by developing a ‘smart and green’ coating that requires no toxic biocides and makes use of copper already present in the water. Biofouling is the unwanted attachment and growth on surfaces in water; it causes significant problems on ships and in drinking water systems, and damages infrastructure and capital investment. Biofouling also carries a significant risk of spre ....Preventing biological growth – a new generation anti-biofouling coatings. The project aims to improve anti-biofouling technology by developing a ‘smart and green’ coating that requires no toxic biocides and makes use of copper already present in the water. Biofouling is the unwanted attachment and growth on surfaces in water; it causes significant problems on ships and in drinking water systems, and damages infrastructure and capital investment. Biofouling also carries a significant risk of spreading diseases and environmental damage through the introduction of invasive marine species. Existing coatings release highly toxic substances into the water, causing untold environmental damage. This project offers a single, comprehensive solution for all of the above problems.Read moreRead less
Improved models of nanoporous carbons for greater fundamental insight and better sustainable technology. Storage of hydrogen and energy from intermittent sources like solar and wind, and 'carbon capture' from coal-fired power stations are essential requirements for a sustainable future. A state-of-the-art computer model will be developed and demonstrated to help deliver these and other technologies for a safe and sustainable future.
Vapour phase detection of chemical warfare agents. This project aims to create luminescent plastic optoelectronic materials that can detect airborne chemical warfare agents, particularly nerve agents. Such agents are often odourless and invisible at lethal concentrations, so technology must detect and identify them before exposure. The intended outcomes are design rules for sensitive and selective materials that can be used in a handheld infield detector to sense chemical warfare agents based on ....Vapour phase detection of chemical warfare agents. This project aims to create luminescent plastic optoelectronic materials that can detect airborne chemical warfare agents, particularly nerve agents. Such agents are often odourless and invisible at lethal concentrations, so technology must detect and identify them before exposure. The intended outcomes are design rules for sensitive and selective materials that can be used in a handheld infield detector to sense chemical warfare agents based on the materials’ photophysical properties, and new analytical methods and sensing protocols. This research will be of interest to security agencies in Australia and internationally, and will better protect our military.Read moreRead less
An account of wetting phenomena on nano-engineered surfaces. This project aims to provide researchers and industry with a toolbox to predict wetting behaviour on surfaces with nanoscale topography. A combined experimental and numerical study will lead to the discovery of the mechanisms by which topographical and chemical properties of the surface trigger the formation of nanostructure-induced air pockets and how these phenomena determine surface wettability. This will provide significant benefi ....An account of wetting phenomena on nano-engineered surfaces. This project aims to provide researchers and industry with a toolbox to predict wetting behaviour on surfaces with nanoscale topography. A combined experimental and numerical study will lead to the discovery of the mechanisms by which topographical and chemical properties of the surface trigger the formation of nanostructure-induced air pockets and how these phenomena determine surface wettability. This will provide significant benefits, as the predictive surface-wettability model will enhance controllability and productivity of diverse manufacturing processes and lead to new applications, high-value products and economic benefits in mining, energy, electronics, biomedicine and other fields.Read moreRead less
Nanostructured non-precious metal and metal-free catalysts for sustainable clean energy generation. The innovative technologies for substitution of precious metal catalysts will be developed and used in fuel cells for clean energy generation in a highly efficient and sustainable form. This effort will lead to the reduction in carbon dioxide emissions and the alleviation of environmental and climate change problems.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100042
Funder
Australian Research Council
Funding Amount
$190,000.00
Summary
UV to mid-infrared fluorescence spectrometer for use in mineral analysis, radiation dosimetry, and laser materials characterisation. Ultraviolet to mid-infrared fluorescence spectrometer for use in mineral analysis, radiation dosimetry and laser materials characterisation: This project will provide equipment with a vast capability to collect ultraviolet to mid-infrared fluorescence with high temporal measurement accuracy, and highly flexible excitation (spectral and temporal). This will enhance ....UV to mid-infrared fluorescence spectrometer for use in mineral analysis, radiation dosimetry, and laser materials characterisation. Ultraviolet to mid-infrared fluorescence spectrometer for use in mineral analysis, radiation dosimetry and laser materials characterisation: This project will provide equipment with a vast capability to collect ultraviolet to mid-infrared fluorescence with high temporal measurement accuracy, and highly flexible excitation (spectral and temporal). This will enhance active research into new glasses and laser crystals, probing of defect states resulting from ionising radiation absorption in environmental and medical dosimetry materials, investigation of novel fluorescence techniques for mineral identification, through to improving chemical detection capability (for example, detection of explosives). The instrument comprises modules that enable excitation in the ultraviolet, visible, and infrared from a tunable laser system, and high-efficiency collection and processing of fluorescence spectra.Read moreRead less