Interfacial and Structural Changes During Digestion of Milk-like Systems. This project aims to enhance the understanding of the behaviour of milk and milk-like systems during digestion. Utilising new Australian research infrastructure the project aims to unlock the complex behaviour across different types of milk (including human breast milk) and infant formulae, linking how enzymes behave towards fat droplets and the consequences for lipid structuring and nutrient transport. The rational design ....Interfacial and Structural Changes During Digestion of Milk-like Systems. This project aims to enhance the understanding of the behaviour of milk and milk-like systems during digestion. Utilising new Australian research infrastructure the project aims to unlock the complex behaviour across different types of milk (including human breast milk) and infant formulae, linking how enzymes behave towards fat droplets and the consequences for lipid structuring and nutrient transport. The rational design of systems that function much more closely to human milk will enable the development of new products with flow on benefits in human nutrition and increased utilisation of products from our dairy industry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100596
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Lithium-Ion Conducting Sulfide Cathodes for All-Solid-State Li–S Batteries. The aim of the project is to develop lithium-ion conducting sulphide cathode materials for high-performance all-solid-state lithium-sulphur (Li–S) batteries. Substituting solid-state electrolyte for liquid electrolyte is the most efficient approach to eliminate the polysulfide shuttle effect, which is the biggest obstacle for the practical application of Li–S batteries based on liquid electrolytes. The project aims to de ....Lithium-Ion Conducting Sulfide Cathodes for All-Solid-State Li–S Batteries. The aim of the project is to develop lithium-ion conducting sulphide cathode materials for high-performance all-solid-state lithium-sulphur (Li–S) batteries. Substituting solid-state electrolyte for liquid electrolyte is the most efficient approach to eliminate the polysulfide shuttle effect, which is the biggest obstacle for the practical application of Li–S batteries based on liquid electrolytes. The project aims to develop novel Li2S-rich cathode materials with high lithium-ion conductivity, which will form the basis of all-solid-state Li–S batteries with high energy density. The new battery is expected to have wide applications in portable electronic devices, electric vehicles and grid-scale renewable energy storage.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100177
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Advanced electron paramagnetic resonance (EPR) facilities for chemical, biological and materials sciences. New instrumentation to advance national research in hydrogen fuel generation from renewable sources, new generation photo-voltaic technologies, novel polymer and other chemical materials and advanced computing systems will be provided by this project. A new high sensitivity electron paramagnetic resonance facility, located at the Australian National University, will serve researchers in the ....Advanced electron paramagnetic resonance (EPR) facilities for chemical, biological and materials sciences. New instrumentation to advance national research in hydrogen fuel generation from renewable sources, new generation photo-voltaic technologies, novel polymer and other chemical materials and advanced computing systems will be provided by this project. A new high sensitivity electron paramagnetic resonance facility, located at the Australian National University, will serve researchers in the ACT region devoted to the broad range of activities summarised above. A particular focus involves novel, biologically inspired energy systems and high efficiency solar cell technology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101306
Funder
Australian Research Council
Funding Amount
$365,000.00
Summary
Porous Metal Phosphonate Ion Exchange Membranes for Redox Flow Batteries. The high-performance storage and utilisation of renewable energy, such as solar and wind energy, will provide a direct response to Australia's energy and climate issues. This project aims to develop porous metal phosphonate ion exchange membranes, which can be used in the redox flow battery, one of the most powerful, large-scale energy storage devices, with large capacity, high efficiency, long life and low cost. The proje ....Porous Metal Phosphonate Ion Exchange Membranes for Redox Flow Batteries. The high-performance storage and utilisation of renewable energy, such as solar and wind energy, will provide a direct response to Australia's energy and climate issues. This project aims to develop porous metal phosphonate ion exchange membranes, which can be used in the redox flow battery, one of the most powerful, large-scale energy storage devices, with large capacity, high efficiency, long life and low cost. The project aims to improve the overall performance and fabrication of redox flow batteries, promote capacity and efficiency, and reduce the cost of renewable energy storage thereby benefiting the Australian economy and environment.Read moreRead less
Highly ordered and tunable extracellular DNA micro- and nanopatterns for investigating the attachment mechanisms of pseudomonas aeruginosa to surfaces. Preventing infectious bacteria from colonising artificial surfaces is a major scientific challenge. New engineered surfaces will be designed to better understand how the important pathogen Pseudomonas aeruginosa sticks to surfaces, facilitating new ways of reducing infections acquired from the surface of, for example, medical devices.
Chlorine Evolution Catalysts for Efferent Seawater Electrolysis. Seawater is the most abundant aqueous resource on earth that is readily accessible at very low costs, but yet to be directly utilised for production of hydrogen fuel and commodity chemicals. This project aims to develop cheap and plentiful carbon-based high performance chlorine evolution electrocatalysts for seawater electrolysis powered by renewable electricity to realise the production of hydrogen, chlorine and sodium hydroxide d ....Chlorine Evolution Catalysts for Efferent Seawater Electrolysis. Seawater is the most abundant aqueous resource on earth that is readily accessible at very low costs, but yet to be directly utilised for production of hydrogen fuel and commodity chemicals. This project aims to develop cheap and plentiful carbon-based high performance chlorine evolution electrocatalysts for seawater electrolysis powered by renewable electricity to realise the production of hydrogen, chlorine and sodium hydroxide directly from seawater. The electrolyser can also be used to treat desalination brine while produce hydrogen and chemicals. The success of the project will set a firm technological foundation for seawater utilisation, which will add to Australian capability to meet future energy and environment challenges.Read moreRead less
Advanced electrocatalysts for ammonia synthesis with validated analysis. Ammonia is one of the most produced chemicals worldwide but current manufacturing industries consume massive amounts of energy and emit harmful greenhouse gases. This project aims to develop a sustainable electrochemical system for ammonia synthesis using electricity and atmospheric nitrogen. A family of porous catalysts with nanoconfined ionic liquids will be developed to drive nitrogen reduction by enhancing the reaction ....Advanced electrocatalysts for ammonia synthesis with validated analysis. Ammonia is one of the most produced chemicals worldwide but current manufacturing industries consume massive amounts of energy and emit harmful greenhouse gases. This project aims to develop a sustainable electrochemical system for ammonia synthesis using electricity and atmospheric nitrogen. A family of porous catalysts with nanoconfined ionic liquids will be developed to drive nitrogen reduction by enhancing the reaction kinetics. Rigorous experimental protocols and novel analytical methods will be developed for quantification of electro-synthesised ammonia. A prototype gas diffusion layer-assisted electrolyser will be demonstrated by coupling with oxygen evolution reactions for selective ammonia synthesis at a reasonable production rate.Read moreRead less
Porphyrin arrays - Light Harvesting in three dimensions. The emulation of photosynthesis, the efficient and sustainable utilization of solar energy using renewable materials represents one of the great scientific challenges. This project will explore one aspect of this by determining the nature and scope of using assemblies of artificial chlorophylls for three dimensional light harvesting in titania solar cells.
Harnessing lipid nano-assembly for next generation functional foods and pharmaceutical products. Nature assembles lipid molecules from our diet into useful structures in our gastrointestinal tract with remarkable precision and versatility. By understanding and harnessing these processes we can design new lipid-based nanomaterials leading to more effective functional foods and pharmaceutical products with reduced side effects.
Anion Exchange Membrane Water Electrolysis for Clean Hydrogen Production. Low-cost and robust water electrolysis technology is a cornerstone towards the success of the hydrogen economy. This project aims to develop next generation anion exchange membrane water electrolyser technologies for low-cost and high-efficiency clean hydrogen production and renewable energy storage. Novel non-precious transition metal-based catalysts with high intrinsic activity, large surface area and super-hydrophilic s ....Anion Exchange Membrane Water Electrolysis for Clean Hydrogen Production. Low-cost and robust water electrolysis technology is a cornerstone towards the success of the hydrogen economy. This project aims to develop next generation anion exchange membrane water electrolyser technologies for low-cost and high-efficiency clean hydrogen production and renewable energy storage. Novel non-precious transition metal-based catalysts with high intrinsic activity, large surface area and super-hydrophilic surfaces will be developed, and their mechanism and stability within membrane electrode assemblies understood by using operando spectroscopy, electrochemistry and 3D X-ray imaging characterisations. An efficient anion exchange membrane water electrolyser prototype made entirely of non-precious materials is to be devised. Read moreRead less