Renewable energy from carbon dioxide: Process engineering to obtain bio-oil from algae. The Stern Report (2007)[1] has called for a CO2 REDUCTION BY MORE THAN 80% in 10-20 years to prevent profound changes in the climate over coming centuries. The proposed project will capture CO2 using algae then off-set the capital investment and on-going expenses of the CO2 capture technology by creating high value products from algae (i.e. bio-diesel, livestock feed and purified water). This process aims to ....Renewable energy from carbon dioxide: Process engineering to obtain bio-oil from algae. The Stern Report (2007)[1] has called for a CO2 REDUCTION BY MORE THAN 80% in 10-20 years to prevent profound changes in the climate over coming centuries. The proposed project will capture CO2 using algae then off-set the capital investment and on-going expenses of the CO2 capture technology by creating high value products from algae (i.e. bio-diesel, livestock feed and purified water). This process aims to be independently profitable regarless of future carbon taxes or carbon trading systems. This project also investigates water purification methods and new livestock feed additives which can help reduce the effects of drought on food producers in rural and regional areas. Read moreRead less
Developing a competitive H2 production suystem based on engineered cells of green algae. The depletion of oil reserves and the effects of global warming make the development of new, clean, sustainable fuel production systems critically important. This frontier technology has the ability to drive solar-powered hydrogen production from water. Extending the system to marine algal cells provides the possibility of coupling clean fuel production with water purification as the product of H2 combustion ....Developing a competitive H2 production suystem based on engineered cells of green algae. The depletion of oil reserves and the effects of global warming make the development of new, clean, sustainable fuel production systems critically important. This frontier technology has the ability to drive solar-powered hydrogen production from water. Extending the system to marine algal cells provides the possibility of coupling clean fuel production with water purification as the product of H2 combustion is pure water. We have already engineered green algae that produce H2 from H2O at a rate ~1000% higher than the Wild-type and through this project will incorporate further improvements with the aim of developing a competitive H2 production system.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
Combining recycled water use, biofuel production and phytoremediation of contaminated land and biosolids. The storage of biosolids, by-products of sewage treatment, is an environmentally unsustainable practice exacerbated by the presence of inorganic and organic contaminants. Phytoremediation is a plant-based technology which is potentially a cost-effective option for progressive long-term and sustainable clean-up of contaminated soils and sediments. Combining metal extraction by plants with r ....Combining recycled water use, biofuel production and phytoremediation of contaminated land and biosolids. The storage of biosolids, by-products of sewage treatment, is an environmentally unsustainable practice exacerbated by the presence of inorganic and organic contaminants. Phytoremediation is a plant-based technology which is potentially a cost-effective option for progressive long-term and sustainable clean-up of contaminated soils and sediments. Combining metal extraction by plants with reuse of wastewater and the production of a biofuel will provide multiple benefits of a cleaner environment, water conservation, waste reduction, carbon capture and a reduction in fossil fuel use. Development of such a low-cost combined bioenergy/remediation system will be of considerable local/regional benefit and national significance.Read moreRead less
Metabolic engineering of Zymomonas mobilis for higher value fermentation products. This project will provide an opportunity to revolutionise the Australian chemical and sugar industries. Unlike the traditional methods of the petrochemical industry, bioconversion of carbohydrates to chemicals such as succinic acid via fermentation is cosiderably environmental friendly. For the sugar industry this project will provide an opportunity to produce not only conventional sugar products but also high val ....Metabolic engineering of Zymomonas mobilis for higher value fermentation products. This project will provide an opportunity to revolutionise the Australian chemical and sugar industries. Unlike the traditional methods of the petrochemical industry, bioconversion of carbohydrates to chemicals such as succinic acid via fermentation is cosiderably environmental friendly. For the sugar industry this project will provide an opportunity to produce not only conventional sugar products but also high value commodities via the process integration of succinic acid production using agricultural residues such as bagasse. This will contribute to significant levels of job creation in Australia, and further benefits will be that such products will be important both for import replacement and export potential.Read moreRead less
Metabolic engineering to develop recombinant Zymomonas mobilis for the production of fuel ethanol and fermentation chemicals. This project will provide an opportunity to revolutionise the Australian chemical and sugar industries. Unlike the traditional methods of the petrochemical industry, bioconversion of carbohydrates to chemicals, such as succinic acid via fermentation is more considerably environmentally friendly. For the sugar industry this project will provide an opportunity to produce no ....Metabolic engineering to develop recombinant Zymomonas mobilis for the production of fuel ethanol and fermentation chemicals. This project will provide an opportunity to revolutionise the Australian chemical and sugar industries. Unlike the traditional methods of the petrochemical industry, bioconversion of carbohydrates to chemicals, such as succinic acid via fermentation is more considerably environmentally friendly. For the sugar industry this project will provide an opportunity to produce not only conventional sugar products but also high value commodities via the process integration of succinic acid production using agricultural residues, such as bagasse. This will contribute to significant levels of job creation in Australia, with the further benefit that such products will be important for both import replacement and export potential.Read moreRead less
Interspecies electron transfer in biotechnology. While the project is fundamental in nature, it has direct technological gains to a wide range of biotechnology processes, and in particular, mixed culture anaerobic biotechnology. It therefore promotes Australian bioenergy, biofuel, and commodity renewable chemicals industries, and contributes to the national research priority of an Environmentally Sustainable Australia. In addition, this is a fast moving, high impact area that will demonstrate e ....Interspecies electron transfer in biotechnology. While the project is fundamental in nature, it has direct technological gains to a wide range of biotechnology processes, and in particular, mixed culture anaerobic biotechnology. It therefore promotes Australian bioenergy, biofuel, and commodity renewable chemicals industries, and contributes to the national research priority of an Environmentally Sustainable Australia. In addition, this is a fast moving, high impact area that will demonstrate excellence in Australian research on an international scale. The exciting multidisciplinary nature of the project, excellent management team, and high-class partners will also provide for an excellent experience for the three PhD candidates to be educated through the project.Read moreRead less
Clean fuels for the future: Scale up and optimisation of microalgal oil production and biodiesel synthesis. The development of renewable carbon-neutral fuels is an urgent challenge facing our society. This project aims to develop an innovative system for biodiesel production from local Australian algae species. If cultivated under the right conditions, microalgae are very efficient near-continuous producers of biodiesel and are likely the only renewable source of fuel that could match our curren ....Clean fuels for the future: Scale up and optimisation of microalgal oil production and biodiesel synthesis. The development of renewable carbon-neutral fuels is an urgent challenge facing our society. This project aims to develop an innovative system for biodiesel production from local Australian algae species. If cultivated under the right conditions, microalgae are very efficient near-continuous producers of biodiesel and are likely the only renewable source of fuel that could match our current and future demand without competing for arable land and food production. Such systems couple the national/community benefits of energy generation, carbon-capture, biodiesel production and the clean-up of wastewater. Successful outcomes from this project will bring this innovative technology closer to commercial reality. Read moreRead less
Second generation biofuels: developing environmentally friendly high-efficiency microalgae for biofuel production. The development of CO2-neutral (biodiesel) and CO2-free (hydrogen) fuels is an urgent challenge facing our society to combat climate change and protect against oil price shocks. Successful outcomes from this project will bring this innovative technology closer to commercial reality. The solar-powered microalgal systems being developed, offer a number of national/community benefits ....Second generation biofuels: developing environmentally friendly high-efficiency microalgae for biofuel production. The development of CO2-neutral (biodiesel) and CO2-free (hydrogen) fuels is an urgent challenge facing our society to combat climate change and protect against oil price shocks. Successful outcomes from this project will bring this innovative technology closer to commercial reality. The solar-powered microalgal systems being developed, offer a number of national/community benefits including
1. A high-efficiency frontier-technology for clean fuel production for the Australian and international market
2. A new process to desalinate water
3. Frontier technology to sequester atmospheric CO2
4. Frontier technologies for wealth generation in drought- or salinity-affected and naturally arid regionsRead moreRead less
Targeted bioengineering and systems biology for solar powered hydrogen production in green algal cells. The development of clean fuels to combat climate change and protect against oil price shocks, is an urgent challenge facing our society. Fuels make up ~67% of the energy market, yet most low-CO2 emissions technologies (e.g. nuclear and clean-coal-technology) target the electricity market. In contrast the Solar Bio-H2 process uses algal photobioreactors to drive solar-powered H2 fuel production ....Targeted bioengineering and systems biology for solar powered hydrogen production in green algal cells. The development of clean fuels to combat climate change and protect against oil price shocks, is an urgent challenge facing our society. Fuels make up ~67% of the energy market, yet most low-CO2 emissions technologies (e.g. nuclear and clean-coal-technology) target the electricity market. In contrast the Solar Bio-H2 process uses algal photobioreactors to drive solar-powered H2 fuel production from water (ultimately sea water, facilitating desalination). This project aims to improve the efficiency of the process towards economical levels. The Solar Bio-H2 process reduces water requirements for biofuel production. Locating bioreactors on non-arable land also eliminates competition between biofuel and food production.Read moreRead less