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Utilising nature's complexity - understanding fundamental organometallic binding modes of furans and coordination of bioderived furans. The earth's decreasing reserves of fossil fuels has prompted an intense push to utilise the renewable bioresources to replace the many products and fuels derived from petroleum. One of the promising developments is the production of so-called Furanics, useful molecules produced easily from carbohydrates found in waste materials from the sugar, corn and forestry ....Utilising nature's complexity - understanding fundamental organometallic binding modes of furans and coordination of bioderived furans. The earth's decreasing reserves of fossil fuels has prompted an intense push to utilise the renewable bioresources to replace the many products and fuels derived from petroleum. One of the promising developments is the production of so-called Furanics, useful molecules produced easily from carbohydrates found in waste materials from the sugar, corn and forestry industries. Given Australia's wealth of agricultural resources, discovering the full power of these potentially useful furanic compounds should be a major priority. This research aims to link Australia's biomass potential with the plastics, pharmaceutical, fine and agrichemical industries.Read moreRead less
Designer Surfactants for Creation of Emulsion Properties. We propose new approaches to the design of surfactants for stabilising water in oil emulsions. New block copolymer surfactants may be "tailored" for head group structure and a pre-chosen hydrophilic/lipophilic balance at the oil-water interface using the Australian developed RAFT polymer synthesis method and polymeric inorganic species. The proposers have an extensive background in these areas.
X-ray and neutron scattering techniques, de ....Designer Surfactants for Creation of Emulsion Properties. We propose new approaches to the design of surfactants for stabilising water in oil emulsions. New block copolymer surfactants may be "tailored" for head group structure and a pre-chosen hydrophilic/lipophilic balance at the oil-water interface using the Australian developed RAFT polymer synthesis method and polymeric inorganic species. The proposers have an extensive background in these areas.
X-ray and neutron scattering techniques, developed by us, allow the interfacial structure of the surfactant to be found and the intellectual "loop" closed in the design process. Preliminary screening will be done using the surface balance and bulk emulsion synthesis.Read moreRead less
High Internal Phase Emulsions - Structure and Rheology Control. Our first SPIRT Grant with ORICA Australia Ltd has successfully identified nanostructures in high internal phase emulsions which confer useful stability and robustness on these industrially important systems. The aim now is to ramify those discoveries both scientifically and technologically in the design of emulsion structure using our, now established, techniques. In particular, the objective is to control both nanoscale and mes ....High Internal Phase Emulsions - Structure and Rheology Control. Our first SPIRT Grant with ORICA Australia Ltd has successfully identified nanostructures in high internal phase emulsions which confer useful stability and robustness on these industrially important systems. The aim now is to ramify those discoveries both scientifically and technologically in the design of emulsion structure using our, now established, techniques. In particular, the objective is to control both nanoscale and mesoscale structure in emulsion formulation, as well as the rheology and stability of emulsion preparations. To do this we plan to use mixed surfactant systems and to study intersurfactant synergic effects on the structure and fluidity of the interfacial material. We believe that the proposed work is unique and that the outcomes will be scientifically novel and also valuable for Australian industry.Read moreRead less
Milk protein denaturation and stabilisation at surfaces. The Australian Dairy Industry, valued at $2.8 billion in 2003-4, is ranked third among rural industries in Australia. Australia exports over 50% of its annual milk production, contributing to 13% of world trade. Exports of dairy products are valued at $2.4 billion. In order for Australia to maintain this position, Australia needs to keep up with its major competitors by ensuring quality and consistency of dairy products is maintained, and ....Milk protein denaturation and stabilisation at surfaces. The Australian Dairy Industry, valued at $2.8 billion in 2003-4, is ranked third among rural industries in Australia. Australia exports over 50% of its annual milk production, contributing to 13% of world trade. Exports of dairy products are valued at $2.4 billion. In order for Australia to maintain this position, Australia needs to keep up with its major competitors by ensuring quality and consistency of dairy products is maintained, and by developing new applications and innovative products. The proposal expects to recruit an exceptional young Australian graduate - a former Rhodes Scholar from Oxford University.Read moreRead less
A new route to linear alpha olefins - catalytic isomerisation of internal olefins. Linear alpha olefins are an extremely important class of chemical building blocks used for everyday consumer products, such as plastics, detergents and lubricants. This research aims to develop a new platform technology for the production of these materials from low cost precursors.
Discovery Early Career Researcher Award - Grant ID: DE200100450
Funder
Australian Research Council
Funding Amount
$425,398.00
Summary
Cooperativity by Design: Unlocking Metal-Metal-Ligand Cooperativity. This proposal aims to deliver efficient chemical hydrogen storage by designing new catalysts to facilitate the storage and release of hydrogen fuel. Hydrogen is an important zero-emission fuel for the low carbon energy future. However, to realise the potential of the hydrogen economy, efficient, cost-effective solutions are required for storage and transportation. This project seeks to provide technological and intellectual adv ....Cooperativity by Design: Unlocking Metal-Metal-Ligand Cooperativity. This proposal aims to deliver efficient chemical hydrogen storage by designing new catalysts to facilitate the storage and release of hydrogen fuel. Hydrogen is an important zero-emission fuel for the low carbon energy future. However, to realise the potential of the hydrogen economy, efficient, cost-effective solutions are required for storage and transportation. This project seeks to provide technological and intellectual advances in chemical hydrogen storage methods. These outcomes are expected to provide environmental and economic benefits for Australia’s developing hydrogen economy, both in the energy export market and locally in utilisation of hydrogen as a sustainable fuel.Read moreRead less
Ultrafast optical non-linearities in robust organometallic materials. This project aims to create organometallic complexes with ultrafast nonlinear optical responses. These robust molecules are intended to be used to prepare surface-supported nanostructures. The project will create materials with reversibly switchable nonlinear optical properties that can control or process incident light beams in photonics technologies. These new materials will have possible applications in future photonics tec ....Ultrafast optical non-linearities in robust organometallic materials. This project aims to create organometallic complexes with ultrafast nonlinear optical responses. These robust molecules are intended to be used to prepare surface-supported nanostructures. The project will create materials with reversibly switchable nonlinear optical properties that can control or process incident light beams in photonics technologies. These new materials will have possible applications in future photonics technologies, potentially creating highly-skilled jobs in Australia and growing Australia’s reputation as a leader in molecular materials science.Read moreRead less
Programmable Organometallics for Spatiotemporal Light Control. This Project aims to develop new materials that control and modify light. The new organometallics from this Project are anticipated to display world record light intensity-dependent absorption and other phenomena. These new programmable molecules are expected to respond to environmental stimuli with precise spatial control. Anticipated outcomes of this Project include environmental sensors and a technology platform for targeted medic ....Programmable Organometallics for Spatiotemporal Light Control. This Project aims to develop new materials that control and modify light. The new organometallics from this Project are anticipated to display world record light intensity-dependent absorption and other phenomena. These new programmable molecules are expected to respond to environmental stimuli with precise spatial control. Anticipated outcomes of this Project include environmental sensors and a technology platform for targeted medical imaging and light-responsive therapies. This Project should provide significant benefits including possible commercialisation of the new materials, enhanced research capacity, training students and a postdoctoral fellow with unique skills, and the strengthening of research linkages with strategic partners.Read moreRead less
New methods assisting the detection and attribution of changes in atmospheric carbon dioxide (CO2) levels. New scientific tools to manage the global environment are an international priority. An Australian breakthrough in technology has the potential to revolutionise the measurement and management of atmospheric carbon dioxide, the single largest anthropogenic contributor to greenhouse warming. The fellowship levers sufficient resources to assess this potential in a number of critical applicatio ....New methods assisting the detection and attribution of changes in atmospheric carbon dioxide (CO2) levels. New scientific tools to manage the global environment are an international priority. An Australian breakthrough in technology has the potential to revolutionise the measurement and management of atmospheric carbon dioxide, the single largest anthropogenic contributor to greenhouse warming. The fellowship levers sufficient resources to assess this potential in a number of critical applications, including: early detection of predicted increases in Southern Ocean carbon dioxide emission; indefinite low cost monitoring of regional carbon flux changes over continental Australia; improved international standards for CO2 measurement; and improved manufacturing components for use world-wide in trace-gas measurement.Read moreRead less
Metal-rich materials for optical limiting. This project aims to create metal- and carbon-rich materials that function as optical limiters over a broad temporal range. The project will create robust molecules that are meant to be used to prepare functional materials. These materials could be used for optical devices and to protect personnel from accidental exposure to intense light sources such as high-power lasers.