Special Research Initiatives - Grant ID: SR180200046
Funder
Australian Research Council
Funding Amount
$758,233.00
Summary
Plasma Bubble Column for one step remediation of PFAS. This project aims to develop a new class of plasma water treatment reactors by combining the effectiveness of atmospheric air plasma with the effective mixing of bubble columns. Non-thermal plasmas have been demonstrated to degrade PFAS at the laboratory scale, but key questions remain on the mechanisms of action and process scaling. This project brings together expertise on plasma engineering, bubble column reactors, modelling and industria ....Plasma Bubble Column for one step remediation of PFAS. This project aims to develop a new class of plasma water treatment reactors by combining the effectiveness of atmospheric air plasma with the effective mixing of bubble columns. Non-thermal plasmas have been demonstrated to degrade PFAS at the laboratory scale, but key questions remain on the mechanisms of action and process scaling. This project brings together expertise on plasma engineering, bubble column reactors, modelling and industrial scaling to address these issues. The expected outcomes of this project are the development and demonstration of a modular, re-deployable plasma bubble column reactor for the one step destruction of PFAS. The benefits of this project are a new low cost method to remediate PFAS contamination.Read moreRead less
Optical fibre photoreactor for removing airborne molecular contaminants and volatile organic carbons for semiconductor fabrication and fuel cell applications. The collaboration integrates concepts from photocatalysis, optical fibre technology and filtration, to solve important issues in the semiconductor fabrication and fuel cell industries. The project will place Australia amongst the world-leaders in novel integrated photocatalytic/filtration techniques and provide significant opportunities fo ....Optical fibre photoreactor for removing airborne molecular contaminants and volatile organic carbons for semiconductor fabrication and fuel cell applications. The collaboration integrates concepts from photocatalysis, optical fibre technology and filtration, to solve important issues in the semiconductor fabrication and fuel cell industries. The project will place Australia amongst the world-leaders in novel integrated photocatalytic/filtration techniques and provide significant opportunities for penetration, in particular, into the US filtration market. The collaboration will afford young Australian-based researchers the opportunity to access technology, expertise and knowledge developed in the US, which is currently unavailable in Australia. It will strengthen ties between UNSW and UMN and provide opportunities for further collaboration.Read moreRead less
Flue Gas and CO2 Geosequestration in Surat and Bowen Basin Coals. Climate change considerations require that CO2 emissions to atmosphere be severely reduced. This is best done in the short term by permanently storing the CO2 underground. Amongst the cheapest and safest options are to use coal seams, which then release valuable methane. The market value of this extra methane is ~$9billion and this reduces the cost of sequestration from ~$56 to $25/t CO2. Coal has a very strong affinity for CO2, ....Flue Gas and CO2 Geosequestration in Surat and Bowen Basin Coals. Climate change considerations require that CO2 emissions to atmosphere be severely reduced. This is best done in the short term by permanently storing the CO2 underground. Amongst the cheapest and safest options are to use coal seams, which then release valuable methane. The market value of this extra methane is ~$9billion and this reduces the cost of sequestration from ~$56 to $25/t CO2. Coal has a very strong affinity for CO2, so flue gas stream from power stations can be injected directly, eliminating the need for equipment to capture the CO2, providing savings of ~$500million for each large power station.Read moreRead less
The Effect of Fines Particles on Production and Permeability of cbm Reservoirs. Coalbed methane (cbm) energy resources in Australia exceed $20b in value. One of the production issues with recovering cbm is fines that are created or exist in the coal, which block gas flow to the recovery wells and damage downstream equipment. Understanding how fines are created and migrate within gas wells and then overcoming this problem, the purpose of this research, could deliver additional gas production wort ....The Effect of Fines Particles on Production and Permeability of cbm Reservoirs. Coalbed methane (cbm) energy resources in Australia exceed $20b in value. One of the production issues with recovering cbm is fines that are created or exist in the coal, which block gas flow to the recovery wells and damage downstream equipment. Understanding how fines are created and migrate within gas wells and then overcoming this problem, the purpose of this research, could deliver additional gas production worth over $1.8billion and reduce maintenance costs related to cbm extraction by $25m per year.Read moreRead less
Reactivity of Carbon-Carbon Composites. This project investigates the reactivity of pitch-coke carbon composites with the aim of minimising oxidative carbon loss from anodes during aluminium smelting. Such carbon loss accounts for about 15 percent of the total carbon consumption in smelting, and its reduction will provide considerable economic benefit besides contributing to mitigation of greenhouse gas emission. In the present project the effect of coke calcination and composite baking temper ....Reactivity of Carbon-Carbon Composites. This project investigates the reactivity of pitch-coke carbon composites with the aim of minimising oxidative carbon loss from anodes during aluminium smelting. Such carbon loss accounts for about 15 percent of the total carbon consumption in smelting, and its reduction will provide considerable economic benefit besides contributing to mitigation of greenhouse gas emission. In the present project the effect of coke calcination and composite baking temperatures on the relationship between anode microstructure and reactivity in oxygen as well as carbon dioxide will be investigated, and optimum process conditions determined for minimum reactive carbon loss during smelting.Read moreRead less
Selective wellbore coatings to control fines damage in coal seam gas wells. This project aims to develop a completely new approach to control solids production in coal seam gas wellbores using a selective phase-inversion polymer coating. The approach will take advantage of the low permeability of mudrocks to form a protective barrier across clay-rich layers while remaining permeable across the gas-producing coal seams. The production of fine solids is a key technical issue affecting the producti ....Selective wellbore coatings to control fines damage in coal seam gas wells. This project aims to develop a completely new approach to control solids production in coal seam gas wellbores using a selective phase-inversion polymer coating. The approach will take advantage of the low permeability of mudrocks to form a protective barrier across clay-rich layers while remaining permeable across the gas-producing coal seams. The production of fine solids is a key technical issue affecting the productivity of coal seam gas wells in Queensland, and leads to 10-15 days’ production downtime a year. The expected outcomes of the project include fundamental understanding of the solids breakage phenomena, a predictive tool to classify potential solids risks in coal seam gas wells, and a novel rock-selective wellbore coating technology to control solids production. The potential economic impacts from the project are lower gas production costs and improved gas supply security.Read moreRead less
Improving biological nitrogen removal by enhanced mixing in non-aerated bioreactors. Mixing has been identified as a key factor in achieving enhanced performance out of existing and upgraded bioreactors. There is currently a poor understanding of the relationship between non-ideal flow and performance in wastewater treatment bioreactors. The project will determine this relationship and subsequently use it to show how reactor performance can be improved, providing first criteria by which mixing c ....Improving biological nitrogen removal by enhanced mixing in non-aerated bioreactors. Mixing has been identified as a key factor in achieving enhanced performance out of existing and upgraded bioreactors. There is currently a poor understanding of the relationship between non-ideal flow and performance in wastewater treatment bioreactors. The project will determine this relationship and subsequently use it to show how reactor performance can be improved, providing first criteria by which mixing can be assessed, and second a systematic methodology for improving reactor performance by improving mixing.Read moreRead less
Supported biomass membrane bioreactor: optimisation of aeration for better fouling control. This project will lead to a sustainable, affordable, energy-efficient treatment system for water reuse. The technology developed will particularly benefit small sewage treatment plants in coastal and isolated communities in Australia, by maximising the utilisation of water resources where water is limited, and by reducing the environmental impact of waste discharges. This project will also strengthen rese ....Supported biomass membrane bioreactor: optimisation of aeration for better fouling control. This project will lead to a sustainable, affordable, energy-efficient treatment system for water reuse. The technology developed will particularly benefit small sewage treatment plants in coastal and isolated communities in Australia, by maximising the utilisation of water resources where water is limited, and by reducing the environmental impact of waste discharges. This project will also strengthen research links between Australian and European institutions through the development of this innovative technology. Local water industries will directly benefit from this frontier research.Read moreRead less
Membranes coupled with physico-chemcial treatment in water reuse: New hybrid systems development and fouling assessment. This project will be useful to sewage treatment systems prevalent in the coastal areas of NSW and Queensland and the interior parts of Northern Territory with isolated communities. Membrane processes are a sustainable technology in wastewater treatment for reuse. The novel pre-treatment and fouling assessment protocol proposed in this study are the keys for the cost-effective ....Membranes coupled with physico-chemcial treatment in water reuse: New hybrid systems development and fouling assessment. This project will be useful to sewage treatment systems prevalent in the coastal areas of NSW and Queensland and the interior parts of Northern Territory with isolated communities. Membrane processes are a sustainable technology in wastewater treatment for reuse. The novel pre-treatment and fouling assessment protocol proposed in this study are the keys for the cost-effective and energy-efficient operation and testing of membrane processes. This project will strengthen research links between Australian and European universities, through the development of an innovative pre-treatment technology. The technology is of direct benefit to reuse applications in Australia and has significant export potential.Read moreRead less
Recycling water and nutrients using a high-rate membrane bioreactor coupled with an ion-exchange system. Australia urgently needs to recycle both water and nutrients to protect its rivers and sustain its agriculture. This project will yield a sustainable, energy-efficient treatment system for water reuse and nutrient recovery. The technology's greater economy and efficiency will benefit decentralised systems in urban centres and small sewage treatment plants in isolated communities alike by en ....Recycling water and nutrients using a high-rate membrane bioreactor coupled with an ion-exchange system. Australia urgently needs to recycle both water and nutrients to protect its rivers and sustain its agriculture. This project will yield a sustainable, energy-efficient treatment system for water reuse and nutrient recovery. The technology's greater economy and efficiency will benefit decentralised systems in urban centres and small sewage treatment plants in isolated communities alike by enabling greater water reuse and by reducing the environmental impact of waste discharges. It will be of immediate benefit to the Australian water industry and to exports. This project will strengthen links in water science between Australian and European institutions.Read moreRead less