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Unravelling the dynamics of nitrous oxide production in wastewater systems. This project aims to unravel the dynamics of Nitrous oxide (N2O) production in wastewater treatment systems by combining continuous stable isotope tracing techniques with innovative experimental design and sophisticated mathematical modelling. Nitrous oxide (N2O) is a potent greenhouse gas and a major contributor to the carbon footprint of wastewater treatment systems. Yet we have a poor understanding of how it is produc ....Unravelling the dynamics of nitrous oxide production in wastewater systems. This project aims to unravel the dynamics of Nitrous oxide (N2O) production in wastewater treatment systems by combining continuous stable isotope tracing techniques with innovative experimental design and sophisticated mathematical modelling. Nitrous oxide (N2O) is a potent greenhouse gas and a major contributor to the carbon footprint of wastewater treatment systems. Yet we have a poor understanding of how it is produced in such systems. The outcomes of this project will benefit Australian water utilities by helping them to reduce N2O emissions.Read moreRead less
Enhanced Prediction of Landfill Gas Emissions Through Geosynthetic Systems. Landfill gas represents an opportunity for electricity generation and carbon abatement: it need not be managed solely for environmental, health or safety risk reasons. However, our ability to predict gas collection and fugitive emissions from landfills capped with geosynthetics liners, in consideration of the myriad of factors that control these processes, is imperfect. Building on recent advances in unsaturated soil mec ....Enhanced Prediction of Landfill Gas Emissions Through Geosynthetic Systems. Landfill gas represents an opportunity for electricity generation and carbon abatement: it need not be managed solely for environmental, health or safety risk reasons. However, our ability to predict gas collection and fugitive emissions from landfills capped with geosynthetics liners, in consideration of the myriad of factors that control these processes, is imperfect. Building on recent advances in unsaturated soil mechanics, this project aims to conduct cutting-edge experimental and theoretical research to develop an experimentally-validated theory of gas migration through geosynthetics systems that is expected to lead to major improvement in performance and provide integrated design tools which are much needed but not currently availableRead moreRead less
Improved predictions of greenhouse gas transfers in landfill composite liner covers containing geomembrane defects. The Australian Greenhouse Office indicated that methane accounted for 85 per cent of the waste sector's annual greenhouse emissions in 2008, and stressed the need to undertake a range of activities to reduce these emissions. Models and theories derived from this project will address specifically the above issue leading to enhanced economic benefits.
Landfill gas leakages in geosynthetic lining systems: closing missing gaps. This project aims to resolve the shortfall in the fundamental understanding of the coupling between gas flow and geosynthetic liner systems by developing practical and new modelling techniques. The project expects to underpin the development of an experimentally validated theory to predict gas leakage rates through geosynthetics composite liner systems. Expected outcomes of the project are the establishment of a new conc ....Landfill gas leakages in geosynthetic lining systems: closing missing gaps. This project aims to resolve the shortfall in the fundamental understanding of the coupling between gas flow and geosynthetic liner systems by developing practical and new modelling techniques. The project expects to underpin the development of an experimentally validated theory to predict gas leakage rates through geosynthetics composite liner systems. Expected outcomes of the project are the establishment of a new conceptual framework and improved integrated design tools for the mitigation of gas escape through geosynthetics liner systems. These outcomes are expected to benefit the waste industry by providing the necessary scientific advances to enable a better estimate of gas emissions from landfills.Read moreRead less
Novel hybrid silica membranes for desalination. This project aims to produce high flux, highly stable ceramic membranes for use in desalination. This will result in novel, low energy desalination processes, delivering potable water at a greatly reduced cost.
Adaptive daytime radiative cooling and heating for buildings . This project aims to develop an adaptive daytime radiative cooling and heating technology suitable for the for the reduction of the energy consumption in buildings for the mitigation of the urban overheating in the built environment. The project expects to generate new knowledge in this area to exploit adaptive strategies in the development of future cooling and heating solutions for buildings. Expected project outcomes consist of th ....Adaptive daytime radiative cooling and heating for buildings . This project aims to develop an adaptive daytime radiative cooling and heating technology suitable for the for the reduction of the energy consumption in buildings for the mitigation of the urban overheating in the built environment. The project expects to generate new knowledge in this area to exploit adaptive strategies in the development of future cooling and heating solutions for buildings. Expected project outcomes consist of the establishment of the new adaptive daytime radiative technology for use on building envelopes to support cooling requirements in hot weather and heating needs under cold conditions. This should lead to significant benefits for the Australian building and construction industry. Read moreRead less
Regulating the Climate Finance Revolution. This project aims to identify how financial market regulators might best incentivise financial institutions to shift from high to low carbon investments, thereby mitigating climate change. It expects to generate new knowledge identifying regulatory excellence in previously uncharted territory and to enable best practice policymaking. Its expected outcomes will be to identify the central roles that the design and implementation of regulation can play in ....Regulating the Climate Finance Revolution. This project aims to identify how financial market regulators might best incentivise financial institutions to shift from high to low carbon investments, thereby mitigating climate change. It expects to generate new knowledge identifying regulatory excellence in previously uncharted territory and to enable best practice policymaking. Its expected outcomes will be to identify the central roles that the design and implementation of regulation can play in fast tracking finance for climate action. Its benefits should include advancing climate change mitigation, facilitating the development of Australia as a competitive sustainable finance market and contributing to Australia’s research on achieving a desirable energy future. Read moreRead less
Anaerobic methane oxidation in the deep sub-seafloor microbial biosphere. Microbes that control the emission of the greenhouse gas methane from the seafloor to the Earth's atmosphere effectively slow global warming. This project aims to understand the microbial controls for this process to improve an understanding of this planet's natural carbon cycle, and yield valuable information for marine CO2 geosequestration strategies.
Activation of small molecules using redox- and pH-stable polyoxometalate molecular clusters as catalysts. Anthropogenic carbon dioxide has been linked to global climate change, and several approaches to reducing emissions have been proposed. This project aims to develop systems that convert carbon dioxide into useful raw materials for the chemical industry and fuel, reducing the need to use additional non-renewable resources for these purposes.
Smart materials for atmospheric water management and water harvesting. Fresh water is a scarce resource in many parts of the globe but uncomfortably over-supplied in other regions. Dehumidifying machines, such as air conditioners, are extensively used in humid climates to enhance human comfort, but with great energy costs. Likewise, the production of potable water in remote dry regions is energy intensive. We propose novel hyper-absorbent desiccating polymers combined into sorption-powered engin ....Smart materials for atmospheric water management and water harvesting. Fresh water is a scarce resource in many parts of the globe but uncomfortably over-supplied in other regions. Dehumidifying machines, such as air conditioners, are extensively used in humid climates to enhance human comfort, but with great energy costs. Likewise, the production of potable water in remote dry regions is energy intensive. We propose novel hyper-absorbent desiccating polymers combined into sorption-powered engines inspired by nastic movements in plants to develop extremely efficient dehumidifiers and water harvesting machines. These polymer actuators can help address the auto-acceleration of climate change caused by the increasing use of air conditioners and provide cheap, clean water for remote communities.Read moreRead less