Computer-Aided Design of High-Performance Photocatalysts for Solar Hydrogen Production Based on Red Titanium Dioxide. Large-scale generation of energy by solar conversion is critical for future sustainability. This project aims to develop high performance materials to efficiently convert solar energy to hydrogen - a clean fuel. Starting from the newly developed material red titanium dioxide, novel strategies for improved photocatalytic materials will be proposed and evaluated by advanced computa ....Computer-Aided Design of High-Performance Photocatalysts for Solar Hydrogen Production Based on Red Titanium Dioxide. Large-scale generation of energy by solar conversion is critical for future sustainability. This project aims to develop high performance materials to efficiently convert solar energy to hydrogen - a clean fuel. Starting from the newly developed material red titanium dioxide, novel strategies for improved photocatalytic materials will be proposed and evaluated by advanced computational approaches. Key issues for solar-to-hydrogen conversion will be clarified. The materials, knowledge and strategies achieved by this project will dramatically enhance current solar technology and in particular will advance the development of low-cost hydrogen production from water. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100100
Funder
Australian Research Council
Funding Amount
$975,934.00
Summary
Multifunctional Platform for Chemical Manufacturing and Energy Materials. We aim to establish the first platform in Australia for the continuous production and in-situ characterisation of molecules and nanomaterials. This project expects to generate new knowledge in the area of functional materials using an interdisciplinary approach. The expected outcomes will be a unique analytical capability for rapid screening of synthetic and operational parameters, and unprecedented fundamental insight int ....Multifunctional Platform for Chemical Manufacturing and Energy Materials. We aim to establish the first platform in Australia for the continuous production and in-situ characterisation of molecules and nanomaterials. This project expects to generate new knowledge in the area of functional materials using an interdisciplinary approach. The expected outcomes will be a unique analytical capability for rapid screening of synthetic and operational parameters, and unprecedented fundamental insight into chemical reactions to inform the design and development of sustainable chemical processes. This proposal will provide significant benefits to cutting-edge research in catalysis, polymer engineering, separation science, CO2 capture and organic synthesis, to positively impact on the energy-manufacturing-environment nexus.Read moreRead less
Centre Of Research Excellence On Sitting Time And Chronic Disease Prevention – Mechanisms, Measurement And Interventions
Funder
National Health and Medical Research Council
Funding Amount
$2,657,874.00
Summary
Australian research has identified serious health consequences arising from the 7 to 10 hours of daily sitting that most people do, especially in relation to ‘diseases of inactivity’ – type 2 diabetes, coronary heart disease and breast and colon cancer – that are an unwelcome burden on individuals, families and health systems. This new research examines the practical feasibility and the preventive-health benefits of changing children’s and adults’ sitting time in schools, workplaces and the home ....Australian research has identified serious health consequences arising from the 7 to 10 hours of daily sitting that most people do, especially in relation to ‘diseases of inactivity’ – type 2 diabetes, coronary heart disease and breast and colon cancer – that are an unwelcome burden on individuals, families and health systems. This new research examines the practical feasibility and the preventive-health benefits of changing children’s and adults’ sitting time in schools, workplaces and the home environment.Read moreRead less
Advanced chemical recycling of mixed plastics for monomer recovery. This project aims to develop innovative catalytic routes to the chemical recycling of mixed plastics for recovery of their molecular building blocks. Plastic pollution poses a significant threat to the Australian ecosystem. Efficient recycling technologies are urgently needed as Australia only recycles ~4% of its 3.4 million tons of mixed waste plastics. This project expects to design highly efficient catalysts for the stepwise ....Advanced chemical recycling of mixed plastics for monomer recovery. This project aims to develop innovative catalytic routes to the chemical recycling of mixed plastics for recovery of their molecular building blocks. Plastic pollution poses a significant threat to the Australian ecosystem. Efficient recycling technologies are urgently needed as Australia only recycles ~4% of its 3.4 million tons of mixed waste plastics. This project expects to design highly efficient catalysts for the stepwise breakdown of mixed polyolefin plastics into monomers for the subsequent manufacturing of virgin plastics in a circular economy, and to elucidate fundamental underpinning reaction mechanisms. Outcomes will stimulate the Australian waste plastic recycling industry, and minimise plastic accumulation in the environment.Read moreRead less
Nanostructured solid acid catalysts for sustainable chemical manufacturing. This project aims to develop next-generation solid acid catalysts for energy- and atom-efficient transformations of waste biomass and carbon dioxide to sustainable chemicals and fuels. Catalysis is a transformative technology, key to both life and lifestyle, contributing to 90% of chemical manufacturing processes and >20% of all industrial products, and will be a key enabler for the emerging Australian bioeconomy. The ex ....Nanostructured solid acid catalysts for sustainable chemical manufacturing. This project aims to develop next-generation solid acid catalysts for energy- and atom-efficient transformations of waste biomass and carbon dioxide to sustainable chemicals and fuels. Catalysis is a transformative technology, key to both life and lifestyle, contributing to 90% of chemical manufacturing processes and >20% of all industrial products, and will be a key enabler for the emerging Australian bioeconomy. The expected development of new high performance catalysts for the production of renewable transportation fuels and sustainable chemical feedstocks will underpin commercially viable low carbon technologies using waste resources, and should provide significant benefits to Australian science, industry, and the environment.
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ARC Centre of Excellence for Green Electrochemical Transformation of Carbon Dioxide. ARC Centre of Excellence for Green Electrochemical Transformation of Carbon Dioxide. This Centre aims to advance carbon dioxide electrochemistry innovations to enable the conversion of carbon dioxide into valuable products and transition Australia to a carbon-neutral economy. This Centre expects to generate new knowledge using experimental and computational approaches to develop systems-level understanding to fu ....ARC Centre of Excellence for Green Electrochemical Transformation of Carbon Dioxide. ARC Centre of Excellence for Green Electrochemical Transformation of Carbon Dioxide. This Centre aims to advance carbon dioxide electrochemistry innovations to enable the conversion of carbon dioxide into valuable products and transition Australia to a carbon-neutral economy. This Centre expects to generate new knowledge using experimental and computational approaches to develop systems-level understanding to furnish industry-ready carbon dioxide utilisation technologies. Expected outcomes include enhanced capacity through collaborations establishing the Centre as an international hub for research, training, technology translation and strategic advice for stakeholders and policymakers. This should accelerate Australia’s progress towards net zero emissions targets and grow a sustainable economy and create future jobs.Read moreRead less
To identify and to understand highly reactive surfaces for solar hydrogen production. This project aims to develop advanced technology to produce hydrogen - carbon-free fuel - from water with sunlight as the only energy input. Using clean energy to replace fossil fuels can help address the issues of energy supply and reduce carbon emissions, which is critically important for a sustainable Australia.
Chiral Catalysts by Rational Design. This project aims to integrate theory and experiment to design new catalysts for the synthesis of multi-stereocentre-containing molecules. Such molecules offer clear advantages in the area of drug design, owing to their potent and selective binding to biological targets, but a lack of available methods for their preparation currently limits their widespread use. This project will use theory to guide the discovery of new ways to make these molecules. It is exp ....Chiral Catalysts by Rational Design. This project aims to integrate theory and experiment to design new catalysts for the synthesis of multi-stereocentre-containing molecules. Such molecules offer clear advantages in the area of drug design, owing to their potent and selective binding to biological targets, but a lack of available methods for their preparation currently limits their widespread use. This project will use theory to guide the discovery of new ways to make these molecules. It is expected that detailed understanding of the factors that control stereocentre formation will be obtained from accurate theoretical modelling and will be applied to invent new catalysts that deliver improved performance and control over product structure.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101014
Funder
Australian Research Council
Funding Amount
$349,785.00
Summary
Extending economic design to non-market settings: An experimental study of mechanism design with intention-based preferences. Mechanism design is the engineering side of economic theory, which starts with assumptions regarding human nature and builds economic systems to best maximise efficiency according to these assumptions. This project studies mechanism design in experimental settings where individuals exhibit a desire to be kind to those who have been kind to them and unkind to those who ha ....Extending economic design to non-market settings: An experimental study of mechanism design with intention-based preferences. Mechanism design is the engineering side of economic theory, which starts with assumptions regarding human nature and builds economic systems to best maximise efficiency according to these assumptions. This project studies mechanism design in experimental settings where individuals exhibit a desire to be kind to those who have been kind to them and unkind to those who have not. Such preferences are common in many non-market settings and can have dramatic effects on the efficiency of potential mechanisms. The ultimate goal of this project is to develop applied mechanisms that are robust to heterogeneity in such intention-based preferences and which can be used in bilateral exchange, contract design and many other non-market settings.Read moreRead less