Hydrogen production from the anaerobic digestion of organic waste using a novel membrane. Solid organic waste is a potentially large, decentralized and sustainable source of hydrogen. The potential hydrogen yield from the anaerobic digestion of solid organic waste in Sydney alone could power over 750,000 passenger vehicles. Hydrogen is always generated in the digestion of organic material, but under natural conditions it is scavenged by methanogens. Recently developed silica membranes are sel ....Hydrogen production from the anaerobic digestion of organic waste using a novel membrane. Solid organic waste is a potentially large, decentralized and sustainable source of hydrogen. The potential hydrogen yield from the anaerobic digestion of solid organic waste in Sydney alone could power over 750,000 passenger vehicles. Hydrogen is always generated in the digestion of organic material, but under natural conditions it is scavenged by methanogens. Recently developed silica membranes are selectively and highly permeable to hydrogen, and these can be used to draw hydrogen from the digester. The digester will be run at high temperatures (>65oC) because this favours organisms that produce hydrogen over methanogens. Anaerobic digesters are well established in Europe and at least 3 municipal plants already exist in Australia.Read moreRead less
Enhancing the productivity of wastewater desalination. Climate change is causing reduced rainfall over much of populated Australia. New technology to enable membrane desalination of wastewater treatment effluent will be developed to provide secure reliable water supplies for Australian (and international) urban and regional communities. Application of the technology to Western Treatment Plant at Werribee will provide up to 10 gigalitres/year of recycled water to the local agricultural, business ....Enhancing the productivity of wastewater desalination. Climate change is causing reduced rainfall over much of populated Australia. New technology to enable membrane desalination of wastewater treatment effluent will be developed to provide secure reliable water supplies for Australian (and international) urban and regional communities. Application of the technology to Western Treatment Plant at Werribee will provide up to 10 gigalitres/year of recycled water to the local agricultural, business and tourism precincts. The economy, community and environment will benefit due to reduced use of potable, river and ground water. Wide application of this technology to wastewater and brackish water will lead to similar benefits and an environmentally sustainable Australia.
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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
Industrial Transformation Research Hubs - Grant ID: IH130200025
Funder
Australian Research Council
Funding Amount
$2,181,756.00
Summary
ARC Research Hub for transforming waste directly in cost-effective green manufacturing. ARC Research Hub for transforming waste directly in cost-effective green manufacturing. This Research Hub aims to create a unique opportunity for completely different industries to come together, with a common goal of creating value from mixed plastic and glass waste in manufacturing. Starting with fundamental investigations of the transformation behaviour of waste materials under high temperature conditions, ....ARC Research Hub for transforming waste directly in cost-effective green manufacturing. ARC Research Hub for transforming waste directly in cost-effective green manufacturing. This Research Hub aims to create a unique opportunity for completely different industries to come together, with a common goal of creating value from mixed plastic and glass waste in manufacturing. Starting with fundamental investigations of the transformation behaviour of waste materials under high temperature conditions, the hub will focus on developing scalable solutions for its manufacturing partners towards reducing the consumption of primary resources while simultaneously diverting waste streams from landfill. Additionally, the potential of using such transformations to yield improved products such as wear-resistant grinding media and light-weight building materials will be investigated to enhance Australian manufacturing.Read moreRead less
Synthesis of Activated Carbon Supported Zero Valent Iron Nanoparticles and Application to Contaminant Degradation in Benthic Sediments. Sediment contamination is a major problem in harbours and estuaries around Australia. For example, in Sydney Harbour, a total fishing ban has been implemented as a result of excessive levels of dioxins and benzofurans in fish tissues. There is also concern at the possibility of large scale contamination of Botany Bay as a result of historic industrial activity a ....Synthesis of Activated Carbon Supported Zero Valent Iron Nanoparticles and Application to Contaminant Degradation in Benthic Sediments. Sediment contamination is a major problem in harbours and estuaries around Australia. For example, in Sydney Harbour, a total fishing ban has been implemented as a result of excessive levels of dioxins and benzofurans in fish tissues. There is also concern at the possibility of large scale contamination of Botany Bay as a result of historic industrial activity around the Bay. While dredging and on-land treatment of sediments is being adopted at the most severely contaminated sites, the cost of this approach is exorbitant. For sites where removal of contaminated sediments cannot be justified, the approach proposed in this study of a technology that entraps contaminants and enhances their in situ biodegradation is potentially a way forward.Read moreRead less
Recycling lignocellulosic agricultural waste as an iron oxide reductant in ferrous processing. This project seeks to recycle agricultural waste as a renewable carbon resource to replace coal-based metallurgical coke as a raw material in ferrous processing. This approach will lead to an innovative recycling of this waste, wherein nothing is wasted and maximum value is extracted from agricultural materials.
Novel recycling approach for automotive waste glass and plastics. This project will develop innovative recycling of automotive waste containing glass and plastics by converting them into value-added material resources. The project outcomes will allow industries to tackle this global waste challenge, reduce landfill burden and enhance waste recycling in Australia.
Endogenous Processes in Biological Wastewater Treatment Systems. Biomass decay, or endogenous processes play a major role in biological wastewater treatment systems, but are poorly understood at present. Drawing on the expertise of four internationally leading groups in the area, we will carry out a comprehensive and profound study of these processes. The study will yield novel designs and operational strategies for wastewater treatment plants that optimise the microbial populations to achieve l ....Endogenous Processes in Biological Wastewater Treatment Systems. Biomass decay, or endogenous processes play a major role in biological wastewater treatment systems, but are poorly understood at present. Drawing on the expertise of four internationally leading groups in the area, we will carry out a comprehensive and profound study of these processes. The study will yield novel designs and operational strategies for wastewater treatment plants that optimise the microbial populations to achieve lower sludge production and higher treatment capacity and performance. It will also deliver a reliable, yet easy to use, model for endogenous processes. Furthermore, a number of highly skilled PhD students will be trained.Read moreRead less
Novel nitrogen removal process via nitrite in a biofilm system and analysis of microbial community dynamics. Nitrogen removal from wastewater is essential to protect our unique aquatic environment. This removal is typically achieved via two steps: Nitrification converts ammonium via nitrite to nitrate; denitrification converts nitrate via nitrite again to harmless nitrogen gas. This project will develop a biofilm reactor system, which enables this process to run via nitrite only, instead of nitr ....Novel nitrogen removal process via nitrite in a biofilm system and analysis of microbial community dynamics. Nitrogen removal from wastewater is essential to protect our unique aquatic environment. This removal is typically achieved via two steps: Nitrification converts ammonium via nitrite to nitrate; denitrification converts nitrate via nitrite again to harmless nitrogen gas. This project will develop a biofilm reactor system, which enables this process to run via nitrite only, instead of nitrate. Savings of 40% carbon and 25% oxygen requirements are possible this way. This process has not yet been demonstrated under controlled conditions, but recent progress in the research groups in Australia and Korea now offer novel ways to accomplish this promising process.Read moreRead less
Enhancing Biological Denitrification by Addition of External Carbon Sources: What, Where and When. External carbon addition for enhancing nitrogen removal is being increasingly used by wastewater treatment industry both in Australia and worldwide. This technology adds considerably to the operating cost, to which the non-optimal use of carbon sources has contributed significantly. To ensure long-term optimal denitrification performance with minimal use of external carbon, we will perform the firs ....Enhancing Biological Denitrification by Addition of External Carbon Sources: What, Where and When. External carbon addition for enhancing nitrogen removal is being increasingly used by wastewater treatment industry both in Australia and worldwide. This technology adds considerably to the operating cost, to which the non-optimal use of carbon sources has contributed significantly. To ensure long-term optimal denitrification performance with minimal use of external carbon, we will perform the first comprehensive study of the impact of external carbon addition on the denitrifying community and denitrification performance and, on this basis, answer the questions of what carbon sources should be used, where and when/how they should be added under various process design and operational conditions.Read moreRead less