Designer solvents to control reaction outcome. This project aims to control outcomes of chemical reactions using specifically designed ionic liquids as solvents. Ionic liquids are distinct from molecular solvents and are underused due to the limited understanding of their effects on chemical processes. We are developing a predictive framework to explain such effects and this project aims to exploit this new knowledge, using both new and rarely applied ionic liquids to control reaction outcomes. ....Designer solvents to control reaction outcome. This project aims to control outcomes of chemical reactions using specifically designed ionic liquids as solvents. Ionic liquids are distinct from molecular solvents and are underused due to the limited understanding of their effects on chemical processes. We are developing a predictive framework to explain such effects and this project aims to exploit this new knowledge, using both new and rarely applied ionic liquids to control reaction outcomes. The significance lies in the ability to optimise reaction outcomes without the need for solvent screening. The innovation lies in the measurement of microscopic interactions between solvent and reagents, and the use of these interactions to affect a given process.Read moreRead less
Cementitious gel: the missing link in understanding the ageing of built infrastructure. Exposure of built reinforced concrete infrastructure to coastal environments causes premature ageing, unplanned remediation and reduced safety. Enhanced forecasting, achieved by advanced methods, including Helium Ion Microscopy and modeling interactions between cement gel, chloride and water, will deliver proactive management of ageing assets.
Discovery Early Career Researcher Award - Grant ID: DE130100970
Funder
Australian Research Council
Funding Amount
$370,600.00
Summary
Solar energy conversion: illuminating the origin of long-lived charge-separated states in organic donor/acceptor blends. The origin of exceptionally long-lived charges in organic donor/acceptor solid-state blends will be established. This will substantially enhance the efficiency and commercial viability of applications that rely on these long-lived charge-separated states, such as organic solar cells.
Hot exciton dissociation in donor / acceptor organic solar cells: breaking the efficiency limit of organic photovoltaics. Australia will benefit from this project in several key areas with immediate impact. The development of an innovative solar cell architecture through the use of hot exiton dissociation will deliver a potential increase in the maximum achievable power conversion efficiency. The experimental results will significantly advance fundamental knowledge of organic solar cells. This ....Hot exciton dissociation in donor / acceptor organic solar cells: breaking the efficiency limit of organic photovoltaics. Australia will benefit from this project in several key areas with immediate impact. The development of an innovative solar cell architecture through the use of hot exiton dissociation will deliver a potential increase in the maximum achievable power conversion efficiency. The experimental results will significantly advance fundamental knowledge of organic solar cells. This has significant economic benefits by making these solar cells more affordable and also opening up the opportunity to use new materials unconstrained by existing proprietary interests. The training of personnel will contribute towards solving the biggest challenge facing the solar industry in Australia: lack of skilled personnel in a highly specialised industry.Read moreRead less
Developing a geophysically relevant conduction model for the upper mantle. The aim of this project is to develop a geophysically relevant proton conduction model for the Earth’s upper mantle. This would allow the robust interpretation of conductivity maps of the interior of the Earth and the discovery of major new mineral deposits. This advance is designed to be achieved through four major initiatives based on recently developed experimental and computational facilities. The project aims to deve ....Developing a geophysically relevant conduction model for the upper mantle. The aim of this project is to develop a geophysically relevant proton conduction model for the Earth’s upper mantle. This would allow the robust interpretation of conductivity maps of the interior of the Earth and the discovery of major new mineral deposits. This advance is designed to be achieved through four major initiatives based on recently developed experimental and computational facilities. The project aims to develop new methods for determining rock conductivities and subsurface mapping from combined datasets. This may provide new insights into the structure and dynamics of the upper mantle as well as providing key data necessary for a national effort aimed at re-establishing Australia as a primary target for mineral exploration.Read moreRead less
ARC Centre of Excellence in Exciton Science. This Centre aims to manipulate the way light energy is absorbed, transported and transformed in advanced molecular materials. The research programme spans high-throughput computational screening, single molecule photochemistry and ultrafast spectroscopy and embraces innovative outreach and commercial translation activities. The Centre plans to capture the knowledge generated as new intellectual property, materials processing know-how, and through the ....ARC Centre of Excellence in Exciton Science. This Centre aims to manipulate the way light energy is absorbed, transported and transformed in advanced molecular materials. The research programme spans high-throughput computational screening, single molecule photochemistry and ultrafast spectroscopy and embraces innovative outreach and commercial translation activities. The Centre plans to capture the knowledge generated as new intellectual property, materials processing know-how, and through the creation of new employment opportunities. The expected outcomes and benefits include new Australian technologies in solar energy conversion, energy-efficient lighting and displays, security labelling and optical sensor platforms for defence.Read moreRead less
Ultra-fast alchemy: a new strategy to synthesise super-dense nanomaterials. We have recently created a new super-dense aluminium phase by ultrafast laser microexplosion. This project will search further for new super-dense material phases with drastically different and exotic properties, such as those inside planets and stars, and which have great potential as new nanomaterials for industrial applications.
Design of adsorbents for kinetic separation of gases. The purpose of this project is to design, synthesise and test a new family of adsorbents for separation of gas mixtures of environmental and energy significance. The outcome will be a thorough understanding of diffusion in adsorbents and preparation of several candidate adsorbents with superior separation characteristics.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100064
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
Optically controlled containers for experiments in soft matter. Nanotechnology has a promising future in the fabrication of small machines but exactly how these machines work is far less certain as they defy fundamental, classical thermodynamics. This equipment will allow Australian researchers to probe the energy dissipation of, and the work done by, small systems, including those of single molecules, colloidal crystals and membranes.
Plasma touches life: advancing plasma technologies for the life sciences. The aim of this project is to develop a mechanistic understanding of how electrically excited gas (plasma) jets deliver reactive oxygen and nitrogen species into tissue, ensuring safety and precision in their use to combat disease. Overcoming barriers in delivery is intended to help realise the full potential of plasma in the life sciences. The project is expected to generate new knowledge across physics, chemistry and bio ....Plasma touches life: advancing plasma technologies for the life sciences. The aim of this project is to develop a mechanistic understanding of how electrically excited gas (plasma) jets deliver reactive oxygen and nitrogen species into tissue, ensuring safety and precision in their use to combat disease. Overcoming barriers in delivery is intended to help realise the full potential of plasma in the life sciences. The project is expected to generate new knowledge across physics, chemistry and biology, leading to new approaches for the future development of plasma technologies. This should provide significant benefits by expanding the human capacity of research in plasma, and in growing the advanced manufacturing of plasma devices for future applications in engineering, biology and health.Read moreRead less