Solar solutions to improve energy affordability for low-income renters. This Project aims to develop solutions for low-income renters to access solar energy. Low-income households spend higher proportions of income on electricity costs. Solar energy is a key way to reduce electricity costs and thus improve energy affordability. Renters are largely excluded from this opportunity. Intended Project outcomes are solutions to access solar energy suitable for widespread application to low-income priva ....Solar solutions to improve energy affordability for low-income renters. This Project aims to develop solutions for low-income renters to access solar energy. Low-income households spend higher proportions of income on electricity costs. Solar energy is a key way to reduce electricity costs and thus improve energy affordability. Renters are largely excluded from this opportunity. Intended Project outcomes are solutions to access solar energy suitable for widespread application to low-income private, public and community rental housing. Adoption of the Project’s outcomes are expected to benefit low-income renters, assist electricity retailers to maintain and extend their customer base, and provide commercial incentives for the many stakeholders providing rental housing and residential solar and battery systems.Read moreRead less
Unravelling the enigma of turbulence by integrating simulation & modelling. This project will transform how turbulence and flow-induced noise is understood and predicted to help meet the challenge of ever-growing transport and energy demands in an affordable and sustainable way. This will be achieved by integrating the latest simulation advances with unique machine-learning approaches. The expected outcome will be a paradigm shift in how turbulence and noise models are created and used, informed ....Unravelling the enigma of turbulence by integrating simulation & modelling. This project will transform how turbulence and flow-induced noise is understood and predicted to help meet the challenge of ever-growing transport and energy demands in an affordable and sustainable way. This will be achieved by integrating the latest simulation advances with unique machine-learning approaches. The expected outcome will be a paradigm shift in how turbulence and noise models are created and used, informed by new scientific knowledge and data. The proliferation of these new models will allow the design and operation of more efficient, reliable and quieter technologies in the aerospace, naval and energy industries, benefitting the Australian economy and environment, and raise the international profile of our scientists.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100429
Funder
Australian Research Council
Funding Amount
$406,177.00
Summary
Bioinspired Photocatalysts for Solar-Driven Hydrogen Peroxide Production. This project aims to develop advanced photocatalysts that can efficiently produce hydrogen peroxide from just water, air, and sunlight. By mimicking the structure and function of the natural photosynthetic apparatus, the key innovations are expected in the design of reaction-oriented conjugated polymer-based photocatalysts at the atomic and molecular nanostructure levels. It expects to generate new knowledge in artificial ....Bioinspired Photocatalysts for Solar-Driven Hydrogen Peroxide Production. This project aims to develop advanced photocatalysts that can efficiently produce hydrogen peroxide from just water, air, and sunlight. By mimicking the structure and function of the natural photosynthetic apparatus, the key innovations are expected in the design of reaction-oriented conjugated polymer-based photocatalysts at the atomic and molecular nanostructure levels. It expects to generate new knowledge in artificial photosynthesis and rational design of functional materials, and sustainable technology for hydrogen peroxide production. This cross-disciplinary research will benefit Australia by the development of biomimetic catalysts for advancing solar energy conversion and enabling sustainable manufacturing of commodity chemicals. Read moreRead less
Innovations in Green Chemical Manufacture from Synchrotron based Techniques. This project aims to find sustainable ways to produce commodity chemicals by developing new catalysts. New synchrotron techniques will be developed and applied to provide new knowledge about the spatial and temporal factors affecting the selectivity and efficiency of electron transfer, redox reactions and diffusion, key for catalyst design. Expected outcomes include the development of new catalysts, new catalyst design ....Innovations in Green Chemical Manufacture from Synchrotron based Techniques. This project aims to find sustainable ways to produce commodity chemicals by developing new catalysts. New synchrotron techniques will be developed and applied to provide new knowledge about the spatial and temporal factors affecting the selectivity and efficiency of electron transfer, redox reactions and diffusion, key for catalyst design. Expected outcomes include the development of new catalysts, new catalyst design concepts and a knowledge repository/database of analytical observations key for unlocking new materials knowledge. This should provide significant economic and environmental benefits by placing Australia at the forefront of the sustainable production of commodity chemicals.Read moreRead less
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
High activity catalysts for CO2 recycling to valuable chemical products. This proposal targets the development of novel porous solid catalysts, containing highly dispersed metal clusters that provide exceptional activity for the conversion (recycling) of carbon dioxide to fuels and other higher value chemical products. These novel materials will improve the productivity and/or reduce the energy required to facilitate the CO2 conversion, thereby reducing costs for industry, whilst also providing ....High activity catalysts for CO2 recycling to valuable chemical products. This proposal targets the development of novel porous solid catalysts, containing highly dispersed metal clusters that provide exceptional activity for the conversion (recycling) of carbon dioxide to fuels and other higher value chemical products. These novel materials will improve the productivity and/or reduce the energy required to facilitate the CO2 conversion, thereby reducing costs for industry, whilst also providing environmental benefit by carbon dioxide utilisation.Read moreRead less