Landfill Based Rapid Anaerobic Digestion of Municipal Solid Waste. The rapid digestion of municipal solid waste has the potential to make putrescible landfills obsolete. Waste can be digested prior to landfilling, eliminating odour and the emission of methane. Pre-digestion is currently performed in highly mechanised in-vessel digesters in some European locations. Demonstations in our laboratory have shown similar digestion rates can be achieved in static beds. This technology can be feasibl ....Landfill Based Rapid Anaerobic Digestion of Municipal Solid Waste. The rapid digestion of municipal solid waste has the potential to make putrescible landfills obsolete. Waste can be digested prior to landfilling, eliminating odour and the emission of methane. Pre-digestion is currently performed in highly mechanised in-vessel digesters in some European locations. Demonstations in our laboratory have shown similar digestion rates can be achieved in static beds. This technology can be feasibly scaled to digest waste streams of the size produced by Australian cities. The project will scale up this technology in a series of test cell trials at the Thiess Swanbank landfill near Ipswich, Queensland.Read moreRead less
Microbial Ecology and Control of Foaming in Anaerobic Digesters. One of the world's most common treatments of biosolids (product of wastewater treatment), anaerobic digestion often suffers from accumulation of biological foam. This foam hinders treatment, personnel health and safety, legal requirements for environmental protection are jeopardised and attempts to control digester foaming are costly. There is a clear lack of knowledge about the organisms involved and causes, therefore no informe ....Microbial Ecology and Control of Foaming in Anaerobic Digesters. One of the world's most common treatments of biosolids (product of wastewater treatment), anaerobic digestion often suffers from accumulation of biological foam. This foam hinders treatment, personnel health and safety, legal requirements for environmental protection are jeopardised and attempts to control digester foaming are costly. There is a clear lack of knowledge about the organisms involved and causes, therefore no informed solutions exist. Molecular DNA techniques, 16SrDNA sequencing and DGGE, will assist in deciphering causes and organisms involved. Research outcomes will present environmental, legal and economical acceptable control strategies for digester foaming to the waste management and water industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101401
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A novel autotrophic biological nitrogen removal process driven by ammonia-oxidising archaea and anammox bacteria. This project will provide fundamental support to the development of more sustainable nitrogen removal processes. This would bring considerable benefits to the Australian wastewater industry and could potentially influence the way that biological nutrient removal plants are designed and operated.
Biological phosphorous removal for wastewater treatment. The aim is to provide a scientific basis for understanding how phosphorous can be removed in wastewater treatment plants, using environmentally safe biological methods rather than by using chemicals. This is expected to lead to improved performance in wastewater treatment plants, which will be of economic and environmental benefit, particularly to regional communities in inland Australia.
In situ microbial conversion of coal to methane: Biotechnology development for clean use of Australian coal. We will develop a biotechnology that uses native microorganisms to accelerate the underground conversion of coal to methane. Approximately 90% of Australia’s coal resources cannot be accessed economically using traditional mining technologies. A technology that converts coal to methane could generate an energy supply worth an estimated $60 billion, foster the development of an energy indu ....In situ microbial conversion of coal to methane: Biotechnology development for clean use of Australian coal. We will develop a biotechnology that uses native microorganisms to accelerate the underground conversion of coal to methane. Approximately 90% of Australia’s coal resources cannot be accessed economically using traditional mining technologies. A technology that converts coal to methane could generate an energy supply worth an estimated $60 billion, foster the development of an energy industry now in its infancy, and generate numerous new employment opportunities. Environmentally, methane is a cleaner burning fuel than coal, uses much less water for processing and generates the same quantity of electricity with lower CO2 emissions. This project highlights the fact that Australia’s microbial diversity is a resource we cannot afford to ignore.Read moreRead less
Biogeochemistry of ferruginous duricrusts. The project is focussed on the examination and application of microbial iron cycling in the formation of geologically stable, iron duricrusts in tropical regimes. The aim of the project is to develop a site-scale bioremediation strategy for iron ore mines by re-establishing canga, which are ‘ancient’ distinct ecosystems possessing unique plant species rarely found on Earth. This university-industry collaboration aims to produce economic benefits for the ....Biogeochemistry of ferruginous duricrusts. The project is focussed on the examination and application of microbial iron cycling in the formation of geologically stable, iron duricrusts in tropical regimes. The aim of the project is to develop a site-scale bioremediation strategy for iron ore mines by re-establishing canga, which are ‘ancient’ distinct ecosystems possessing unique plant species rarely found on Earth. This university-industry collaboration aims to produce economic benefits for the world’s iron mining industry through advanced training in mining-related research, and through the completion of the mining life cycle by site remediation, enhancing Australia’s position as a global leader in providing innovative solutions to today’s mining challenges.Read moreRead less
Breaking critical barriers in soil formation of bauxite residues . Conventional methods of bauxite residue rehabilitation require expensive and unsustainable covering topsoil. Building on recent breakthroughs in eco-engineering tailings into soil, the project aims to develop a field-based technology using marine microbes and halophytic plants to accelerate in-situ soil formation from bauxite residues (incl seawater neutralised bauxite residues) under field conditions. The technology will be unde ....Breaking critical barriers in soil formation of bauxite residues . Conventional methods of bauxite residue rehabilitation require expensive and unsustainable covering topsoil. Building on recent breakthroughs in eco-engineering tailings into soil, the project aims to develop a field-based technology using marine microbes and halophytic plants to accelerate in-situ soil formation from bauxite residues (incl seawater neutralised bauxite residues) under field conditions. The technology will be underpinned by understanding the roles of marine microbe consortia and eco-engineering inputs in accelerating key mineralogical, geochemical, physical and biological changes in bauxite residues. This technology is expected to be transferable and adaptable across other alumina refineries in Australia.Read moreRead less
Fundamental Knowledge Generation of Organic Solid Waste-Microorganism Interactions. The management of organic solid waste is a major global environmental issue, exacerbated by increasing populations and urbanisation. However, there are biological processes (e.g. anaerobic composting) that show excellent potential as the solution to this global problem. We know that the rate-limiting step to biological organic solid waste degradation is the initial hydrolysis process carried out by microorganisms ....Fundamental Knowledge Generation of Organic Solid Waste-Microorganism Interactions. The management of organic solid waste is a major global environmental issue, exacerbated by increasing populations and urbanisation. However, there are biological processes (e.g. anaerobic composting) that show excellent potential as the solution to this global problem. We know that the rate-limiting step to biological organic solid waste degradation is the initial hydrolysis process carried out by microorganisms. We will study at a microscale the "organic solid waste surface-microorganism" interactions and compare data from digesters with the rumen which is a highly efficient model solid substrate digestion system. Our generated knowledge will be used in future practical applications.Read moreRead less
EXTRACELLULAR ELECTRON TRANSFER IN BIO-ELECTROCHEMICAL SYSTEMS. Water quality and supply are critical issues in Australia. This project investigates the role of bacteria in maintaining a good freshwater quality, and the influence of environmental parameters on this. It will enable us to assess the role of bacteria on greenhouse gas emissions in a variety of environments. As a result, processes can be developed to alleviate high emissions while simultaneously producing green energy. The proteomic ....EXTRACELLULAR ELECTRON TRANSFER IN BIO-ELECTROCHEMICAL SYSTEMS. Water quality and supply are critical issues in Australia. This project investigates the role of bacteria in maintaining a good freshwater quality, and the influence of environmental parameters on this. It will enable us to assess the role of bacteria on greenhouse gas emissions in a variety of environments. As a result, processes can be developed to alleviate high emissions while simultaneously producing green energy. The proteomics study will deliver, aside from knowledge, redox proteins which find their way to diagnostics and fuel cells. This project substantiates Australia based research at the forefront and enables international anchoring of our expertise.Read moreRead less
Revolutionising real-time genomic epidemiology in urban wastewater systems. This project aims to develop a real-time and high-resolution genomic tool to monitor and track pathogens in urban wastewater systems based on the portable third-generation sequencing platform. Pathogens sicken hundreds of millions of people, cost the global economy tens of billions of dollars annually, and are one of the leading causes of death worldwide. The current epidemiology approach, and data, are retrospective and ....Revolutionising real-time genomic epidemiology in urban wastewater systems. This project aims to develop a real-time and high-resolution genomic tool to monitor and track pathogens in urban wastewater systems based on the portable third-generation sequencing platform. Pathogens sicken hundreds of millions of people, cost the global economy tens of billions of dollars annually, and are one of the leading causes of death worldwide. The current epidemiology approach, and data, are retrospective and thus insufficient for timely intervention. Integrated with wastewater analysis for pharmaceuticals targeting pathogens, the sewer-based epidemiology approach of this project will greatly enhance public health by achieving early detection and informed control of infectious diseases.Read moreRead less