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.
Disassembly Automation of End-of-Life Electric Vehicle Batteries. This project aims to develop an automated disassembly solution for End-of-Life (EOL) Electric Vehicle (EV) batteries, which is flexible and modular to handle the uncertainties associated with model changes, condition of the EOL battery packs as well as the projected volume growth. The outcome of this project will lead to a better separation of EV battery components and materials. This will allow recycling of EOL EV batteries with ....Disassembly Automation of End-of-Life Electric Vehicle Batteries. This project aims to develop an automated disassembly solution for End-of-Life (EOL) Electric Vehicle (EV) batteries, which is flexible and modular to handle the uncertainties associated with model changes, condition of the EOL battery packs as well as the projected volume growth. The outcome of this project will lead to a better separation of EV battery components and materials. This will allow recycling of EOL EV batteries with a higher material recovery efficiency and a lower cost due to the significantly reduced labor cost; hence substantially reduce the environmental footprint associated with EOL treatment of these batteries.Read moreRead less
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
Drying sewage sludge using hot oil. The project seeks to investigate and develop an entirely new area of fundamental and applied research involving the process, mechanisms and kinetics of direct dehydration of sewage sludge by fry-drying in hot oil. Frying can be carried out as a drying process, though it not widely recognized or applied in this way, and has consequently not been exploited outside of the traditional food industries. It potentially provides a wide range of significant benefits ....Drying sewage sludge using hot oil. The project seeks to investigate and develop an entirely new area of fundamental and applied research involving the process, mechanisms and kinetics of direct dehydration of sewage sludge by fry-drying in hot oil. Frying can be carried out as a drying process, though it not widely recognized or applied in this way, and has consequently not been exploited outside of the traditional food industries. It potentially provides a wide range of significant benefits for sludge drying, including high efficiency and low costs, and produces a non-offensive product with a high energy value suitable for (renewable) power generation.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
Methane and nitrous oxide emissions from sewers – understanding, modelling and mitigation. The research and industry partners will collaborate on this project to quantify, understand and mitigate emissions of methane and nitrous oxide in sewer networks. Both methane and nitrous oxide are potent greenhouse gases, and their emissions need to be accounted for and mitigated for the water industry to achieve greenhouse neutral water services.
Variable speed diesel power conversion system using a doubly fed induction generator. The proposed Variable Speed Diesel Generator to be developed as part of this project will use less fuel and run cleaner with reduced wear than conventional generators. The widespread use of this technology in remote area diesel and hybrid power systems with renewable energy sources will result in a reduction of greenhouse gas emissions. The project will result in enhanced national and international market oppor ....Variable speed diesel power conversion system using a doubly fed induction generator. The proposed Variable Speed Diesel Generator to be developed as part of this project will use less fuel and run cleaner with reduced wear than conventional generators. The widespread use of this technology in remote area diesel and hybrid power systems with renewable energy sources will result in a reduction of greenhouse gas emissions. The project will result in enhanced national and international market opportunities for Australian made power generation equipment for rural electrification. This project will enable Australian companies to be on the leading edge of mini to medium size stand-alone mini grid diesel power stations. This will have a significant impact on the economic development and on job creation in AustraliaRead moreRead less
Special Research Initiatives - Grant ID: SR180100021
Funder
Australian Research Council
Funding Amount
$900,000.00
Summary
PFAS source zone remediation by foam fractionation and in situ fluidisation. This project aims to develop two methods for the in situ remediation of per- and poly-fluroalkyl substances (PFAS) contamination, downhole foam fractionation for in situ groundwater treatment, and in situ fluidisation for soil treatment, both separately and in combination. Using these methods, PFASs will be removed in the form of a foam, which will be extracted as a liquid concentrate. These techniques could enable PFAS ....PFAS source zone remediation by foam fractionation and in situ fluidisation. This project aims to develop two methods for the in situ remediation of per- and poly-fluroalkyl substances (PFAS) contamination, downhole foam fractionation for in situ groundwater treatment, and in situ fluidisation for soil treatment, both separately and in combination. Using these methods, PFASs will be removed in the form of a foam, which will be extracted as a liquid concentrate. These techniques could enable PFAS removal efficiencies of greater than 90%, providing entirely new methods for the aggressive removal of PFAS from contaminated source zones. This project will enable the rapid removal of the bulk of the PFAS present in soils and groundwater and reduce the potential for further spreading.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100451
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Novel biotreatment for micropollutant removal from contaminated water. Micropollutants in contaminated water create major environmental challenges to water resource management in Australia. This project will use a novel biological process to remove micropollutants from water resources sustainably and ensure clean drinking water for Australians.