Revolutionising protection against air pollution. This interdisciplinary project aims to develop a personalised air pollution exposure monitoring system, leveraging the ubiquitousness and advancements in mobile phone technology and state of the art miniaturisation of monitoring sensors, data transmission and analysis. Airborne pollution is one of the top contemporary risks faced by humans; however, at present individuals have no way to recognise that they are at risk or need to protect themselve ....Revolutionising protection against air pollution. This interdisciplinary project aims to develop a personalised air pollution exposure monitoring system, leveraging the ubiquitousness and advancements in mobile phone technology and state of the art miniaturisation of monitoring sensors, data transmission and analysis. Airborne pollution is one of the top contemporary risks faced by humans; however, at present individuals have no way to recognise that they are at risk or need to protect themselves. It is expected that the outcome will empower individuals to control and minimise their own exposures. This is expected to lead to significant national socioeconomic benefits and bring global advancement in acquiring and utilising environmental information.Read moreRead less
A Fundamental Understanding of Methane Driven Denitrification. Eutrophication in waterways due to the presence of nutrients including nitrogen is a well-recognised environmental problem. Moreton Bay, for example, used to receive 3,300 tons of nitrogen each year from point sources. Stringent nitrogen discharge limits have therefore been imposed on most wastewater treatment systems across Australia. Nitrogen removal from wastewater is commonly accomplished in a biological way involving the use of ....A Fundamental Understanding of Methane Driven Denitrification. Eutrophication in waterways due to the presence of nutrients including nitrogen is a well-recognised environmental problem. Moreton Bay, for example, used to receive 3,300 tons of nitrogen each year from point sources. Stringent nitrogen discharge limits have therefore been imposed on most wastewater treatment systems across Australia. Nitrogen removal from wastewater is commonly accomplished in a biological way involving the use of bacteria. The project aims to investigate a particular bacterial community, which is able to perform nitrogen removal from wastewater with methane as a renewable carbon source. The project will therefore lead to more sustainable wastewater treatment systems.Read moreRead less
Biofilm control in wastewater systems using free nitrous acid - a renewable material from wastewater. This project will deliver a technology and the underpinning science to deactivate and remove biofilms in wastewater systems using a renewable material that is produced from wastewater at a low cost. The technology has the potential to revolutionise the management of wastewater systems, bringing massive benefits to the water industry.
Fundamental study on hydrogen desorption from nanoscale Magnesium (Mg) hydrides. Hydrogen storage is the most challenge in realizing the hydrogen economy, especially for on-board application in hydrogen-driving vehicles. Magnesium is among the few promising candidates of effective, safe, high density and cheap hydrogen storage, which has attracted tremendous interests of research. This project creates an innovative science and technology to solve the critical problem of hydrogen storage that wil ....Fundamental study on hydrogen desorption from nanoscale Magnesium (Mg) hydrides. Hydrogen storage is the most challenge in realizing the hydrogen economy, especially for on-board application in hydrogen-driving vehicles. Magnesium is among the few promising candidates of effective, safe, high density and cheap hydrogen storage, which has attracted tremendous interests of research. This project creates an innovative science and technology to solve the critical problem of hydrogen storage that will enhance the international reputation and impact of Australian research in nanoscience and nanothechnology. Realizing the practical hydrogen storage will also enable hydrogen vehicles soon in Australia that adds Australia great potential to reducing the reliance on fossil fuels and greenhouse emissions.Read moreRead less
Multiphase flow and transport in complex coastal wetland systems. Salt marshes play an essential role in maintaining Australia's coastal bio-diversity. They also function as barriers to fluxes of terrestrial pollutants to our coastal sea. Australia has a large number of salt marshes listed by the Ramsar Convention as coastal wetlands of international importance but many of them are subject to loss and degradation due to competing land uses. This project, examining in detail the flow and transpor ....Multiphase flow and transport in complex coastal wetland systems. Salt marshes play an essential role in maintaining Australia's coastal bio-diversity. They also function as barriers to fluxes of terrestrial pollutants to our coastal sea. Australia has a large number of salt marshes listed by the Ramsar Convention as coastal wetlands of international importance but many of them are subject to loss and degradation due to competing land uses. This project, examining in detail the flow and transport processes in marsh soils, will lead to (1) better understanding of the marsh's response to anthropogenic stress; and (2) improvement of strategies and methods for marsh wetland preservation and restoration.Read moreRead less
Understanding Fugitive Greenhouse Gas Emissions from Wastewater Systems for Reliable Accounting and Effective Mitigation. Climate change caused by greenhouse gas (GHG) emissions is one of the most serious challenges facing mankind. Substantial reductions in emissions must be achieved, with responsibility shared by all industrial sectors. Wastewater systems contribute to GHG emission through not only energy consumption but also direct emissions of fugitive GHG such as methane and nitrous oxide. T ....Understanding Fugitive Greenhouse Gas Emissions from Wastewater Systems for Reliable Accounting and Effective Mitigation. Climate change caused by greenhouse gas (GHG) emissions is one of the most serious challenges facing mankind. Substantial reductions in emissions must be achieved, with responsibility shared by all industrial sectors. Wastewater systems contribute to GHG emission through not only energy consumption but also direct emissions of fugitive GHG such as methane and nitrous oxide. This project aims to deliver the urgently needed knowledge and technology support to the Australian wastewater industry to achieve reductions in fugitive emissions. The research will also provide support to the greenhouse office via more reliable estimation of such emissions.Read moreRead less
Biotransformation and biodegradation of organic nitrogen compounds from wastewater in bio-electrochemical systems. The rapid emergence of water recycling in Australia requires more vigilant control of pollutants that are discharged to sewers. This project will develop a novel, cost-effective process to remove organic nitrogen compounds (and likely other organics) present in many industrial wastewaters. It could provide an excellent solution for the pre-treatment of such industrial wastewaters at ....Biotransformation and biodegradation of organic nitrogen compounds from wastewater in bio-electrochemical systems. The rapid emergence of water recycling in Australia requires more vigilant control of pollutants that are discharged to sewers. This project will develop a novel, cost-effective process to remove organic nitrogen compounds (and likely other organics) present in many industrial wastewaters. It could provide an excellent solution for the pre-treatment of such industrial wastewaters at the source without any chemical addition, hence reducing the challenge and risks facing the water recycling plants. This innovative technology will further expand the growing research capacity and know-how in water recycling in Australia.Read moreRead less
A landfill cover that generates electricity: a Microbial Fuel Cell application. Landfills account for over two per cent of Australia’s greenhouse emissions, dominating emissions from waste and wastewater. Methane emissions are inherent to landfills because waste cannot be permanently sealed until a landfill cell is full. In this project, a microbial fuel cell (MFC) landfill cover will be developed as a means of achieving full biogas capture, from the time that waste is placed. The MFC cover syst ....A landfill cover that generates electricity: a Microbial Fuel Cell application. Landfills account for over two per cent of Australia’s greenhouse emissions, dominating emissions from waste and wastewater. Methane emissions are inherent to landfills because waste cannot be permanently sealed until a landfill cell is full. In this project, a microbial fuel cell (MFC) landfill cover will be developed as a means of achieving full biogas capture, from the time that waste is placed. The MFC cover system would consist of a relatively thin and deformable granular graphite layer colonised by current generating methane oxidising microorganisms, overlain by a proton exchange membrane and steel mesh as the anode layer. The MFC cover will provide the benefit of power generation as well as more complete greenhouse gas mitigation. Read moreRead less
Novel Concept for Wastewater Treatment with Integrated Power Production based on Microbial Fuel Cells. Microbial fuel cells are a novel process concept that enables organics, such as sugars, to be converted directly to electricity with the help of naturally occurring microorganisms. This technology has particularly exciting applications in the environmental field, namely in wastewater treatment. It offers significant benefits over current processes, particularly reduced energy consumption or eve ....Novel Concept for Wastewater Treatment with Integrated Power Production based on Microbial Fuel Cells. Microbial fuel cells are a novel process concept that enables organics, such as sugars, to be converted directly to electricity with the help of naturally occurring microorganisms. This technology has particularly exciting applications in the environmental field, namely in wastewater treatment. It offers significant benefits over current processes, particularly reduced energy consumption or even electricity generation and lower sludge production. This project will demonstrate the performance and application of such microbial fuel cells for the removal of organic and nitrogen-based pollutants from wastewater. If successful, this technology offers major advances in both water treatment and renewable energy aspects.Read moreRead less
Micro-managed biofilm - next generation environmental biotechnologies. Eutrophication in waterways due to the presence of nitrogen creates major environmental challenges in inland Australia. This project will develop novel biological nitrogen removal technology, through management of microbial composition to achieve sustainable high-level nitrogen removal from wastewaters and benefical reuse of the water.