Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100193
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
Super High Resolution Correlative Microscopy: New Research Capability for Bioengineering, Clean Energy, Mineral Processing and Environmental Sciences. Super high resolution correlative microscopy: new research capability for bioengineering, clean energy, mineral processing and environmental sciences: This project will establish the first facility for super high resolution correlative microscopy in Australia. This facility will underpin breakthrough science by providing the capability to combine ....Super High Resolution Correlative Microscopy: New Research Capability for Bioengineering, Clean Energy, Mineral Processing and Environmental Sciences. Super high resolution correlative microscopy: new research capability for bioengineering, clean energy, mineral processing and environmental sciences: This project will establish the first facility for super high resolution correlative microscopy in Australia. This facility will underpin breakthrough science by providing the capability to combine and overlay conventional and super high resolution light microscopy information with electron microscopy information on identical sample locations. This new capability will foster advances in the fundamental understanding of multiscale hybrid organic and inorganic structures and spur the development of advanced (nano)materials and devices with broad applications in bioengineering and biofouling, advanced materials for life sciences, clean energy, water and the environment and mineral processing.Read moreRead less
Smart hybrid nano-biomaterials that mimic the pharmaceutical food effect. Smart biomaterials will be developed which when taken orally will act in our gut to improve drug and vitamin uptake. The breakthrough science will drive new pharmaceuticals and nutraceuticals for the future health of Australia, and economic benefits will result through increased exposure to the global market for delivering biomolecules.
Discovery Early Career Researcher Award - Grant ID: DE120100042
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Study of oriented attachment of nanocrystals at oil-water interfaces. This project will study the fundamental issues for crystal growth, which will dramatically facilitate the development of effective pathways for the synthesis of advanced nanomaterials for nanodevice and nanotechnology. The obtained outcomes will enhance our knowledge in crystal growth and colloid sciences.
Taming light and electrons in optical fibres. This project aims to add electrical conduction functionality to optical fibres to manipulate light with electrons and vice versa in a photonics platform, which could bridge the gap between photonics and electronics. It will achieve electrical conduction in optical fibres by creating conductive phases within and onto glass using fibre drawing and polymerisation. The project is expected to lead to breakthroughs in fundamental science at the interfaces ....Taming light and electrons in optical fibres. This project aims to add electrical conduction functionality to optical fibres to manipulate light with electrons and vice versa in a photonics platform, which could bridge the gap between photonics and electronics. It will achieve electrical conduction in optical fibres by creating conductive phases within and onto glass using fibre drawing and polymerisation. The project is expected to lead to breakthroughs in fundamental science at the interfaces between photonics, electronics and materials engineering, and develop optical fibres that change functionalities and applications of optical fibre devices.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100324
Funder
Australian Research Council
Funding Amount
$394,318.00
Summary
Cooperative Single Atom Catalysts for Zn-CO2 Batteries. This project aims to develop cooperative single-atom catalysts for efficient and selective electrocatalytic CO2 conversion and Zn-CO2 batteries. Cooperative catalysts at the single atom limit can potentially achieve enhanced electrochemical properties beyond state-of-the-art and will trigger significant theoretical and technological interests in energy conversion and storage fields. It is expected to generate new knowledge in materials scie ....Cooperative Single Atom Catalysts for Zn-CO2 Batteries. This project aims to develop cooperative single-atom catalysts for efficient and selective electrocatalytic CO2 conversion and Zn-CO2 batteries. Cooperative catalysts at the single atom limit can potentially achieve enhanced electrochemical properties beyond state-of-the-art and will trigger significant theoretical and technological interests in energy conversion and storage fields. It is expected to generate new knowledge in materials science and electrochemistry, using interdisciplinary approaches of atom-precise material engineering, in situ characterisation and full-cell optimisation. Significant economic and environmental benefits are expected from developing carbon-neutral CO2 electrolysers with low cost and high energy efficiency.Read moreRead less
Molecular movies using time-resolved momentum spectroscopies. This project aims to use time-resolved momentum spectroscopies to take snapshots of chemical and physical processes as they evolve in time. This project expects to use these molecular movies to track the changes to electron motion after they have absorbed light. Expected outcomes of this project include understanding how the motion of electrons can drive physical processes and induce chemical changes. This will provide significant ben ....Molecular movies using time-resolved momentum spectroscopies. This project aims to use time-resolved momentum spectroscopies to take snapshots of chemical and physical processes as they evolve in time. This project expects to use these molecular movies to track the changes to electron motion after they have absorbed light. Expected outcomes of this project include understanding how the motion of electrons can drive physical processes and induce chemical changes. This will provide significant benefits through expanding knowledge that will assist in controlling chemical reactions and developing technologies with improved performance, such as sensors and solar cells. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101244
Funder
Australian Research Council
Funding Amount
$417,276.00
Summary
Advanced zinc-ion batteries with high voltage and high energy density. Zinc-ion battery is not only cheaper than current lithium-ion battery (LIB), but it is safer due to a neutral aqueous electrolyte. However, its grid-scale development is plagued by limited output voltage and inadequate energy density compared with more mainstream LIB. This project aims to solve the discharge-voltage problem by fabricating atomic-level structure engineered manganese (Mn)-based cathode and a new stable solid-st ....Advanced zinc-ion batteries with high voltage and high energy density. Zinc-ion battery is not only cheaper than current lithium-ion battery (LIB), but it is safer due to a neutral aqueous electrolyte. However, its grid-scale development is plagued by limited output voltage and inadequate energy density compared with more mainstream LIB. This project aims to solve the discharge-voltage problem by fabricating atomic-level structure engineered manganese (Mn)-based cathode and a new stable solid-state electrolyte, and improve the device energy density by zinc (Zn) anode interface nanotechnology. The success of this project will benefit Australia’s access to new markets and introduce a new low-cost and safe energy storage technology for the long-term viability of Australia’s abundant Zn and Mn resources.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101788
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Shape sorting of nanoparticles at oil-water interfaces in microchannels. This project aims to study the effect of shape on the adsorption of nanoparticles at an oil/water interface and develop a rapid, inexpensive, efficient, versatile method for shape sorting of nanoparticles using a microfluidic approach. This technique can be applied for fractionation of synthetic nanoparticles, biosample analysis and environmental monitoring.
Nanostructured Electrocatalysts for Clean Fuels Production. This project aims to develop single-component and hybrid transition-metal and metal-free electrocatalysts with controllable nanostructures to efficiently and selectively catalyse carbon dioxide reduction and hydrogen evolution reactions for clean fuels production including hydrogen and low-carbon organic molecules. By combining experimental and theoretical modelling, this project plans to reveal the origins, mechanism and pathway of the ....Nanostructured Electrocatalysts for Clean Fuels Production. This project aims to develop single-component and hybrid transition-metal and metal-free electrocatalysts with controllable nanostructures to efficiently and selectively catalyse carbon dioxide reduction and hydrogen evolution reactions for clean fuels production including hydrogen and low-carbon organic molecules. By combining experimental and theoretical modelling, this project plans to reveal the origins, mechanism and pathway of these reactions, and the effect of catalyst composition and morphology on their performance. The resulting nanostructured catalysts are of great importance for feasible clean fuel generation and carbon dioxide reduction.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101163
Funder
Australian Research Council
Funding Amount
$365,000.00
Summary
Design of Nanostructured Electrocatalysts for Water Splitting. The project intends to develop electrocatalysts for water splitting (where a chemical reaction separates water into oxygen and hydrogen, providing clean renewable fuel). The efficient use of renewable energy to generate clean fuels will provide a direct solution to the energy issues in Australia. This project aims to develop new catalysts for the water splitting process by taking into account their electronic structures and verifying ....Design of Nanostructured Electrocatalysts for Water Splitting. The project intends to develop electrocatalysts for water splitting (where a chemical reaction separates water into oxygen and hydrogen, providing clean renewable fuel). The efficient use of renewable energy to generate clean fuels will provide a direct solution to the energy issues in Australia. This project aims to develop new catalysts for the water splitting process by taking into account their electronic structures and verifying their apparent activities in devices. The universal principles to be discovered in the project may be important for the discovery of new electrocatalysts for key energy conversion reactions to develop a feasible clean energy infrastructure and solve environmental issues.Read moreRead less