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Energy from microalgae: industrial scale development and downstream processing of co-products. In this project Australian researchers will develop processes to produce renewable energy and commodity chemicals from microalgae grown in open saline ponds, enabling sustainable production of commercial quantities of clean biofuels and commodity products for the future. Renewable energy is an essential part of Australia's low greenhouse gas emissions energy target and is central to energy security. Th ....Energy from microalgae: industrial scale development and downstream processing of co-products. In this project Australian researchers will develop processes to produce renewable energy and commodity chemicals from microalgae grown in open saline ponds, enabling sustainable production of commercial quantities of clean biofuels and commodity products for the future. Renewable energy is an essential part of Australia's low greenhouse gas emissions energy target and is central to energy security. The development of microalgal energy will help Australia's determination to meet its Kyoto target. Additional benefits will include the development of value-added co-products from microalgal biomass, which is one route to commercial success of the novel technology.Read moreRead less
Bio-oil/char slurry from biomass for co-combustion in coal power plants: achieving power generation with a significant reduction of CO2 emission. This project will develop an advanced co-combustion technology of bio-oil/char slurry (i.e. bioslurry), prepared from biomass pyrolysis products, and coal in the existing coal-fired power plants for achieving significant CO2 reduction. It will enhance Australia's competitive advantage through high impact scientific and technological innovations.
The Permeation of Water through Industrial Membrane Systems. This project aims to understand the permeation of water through commercially relevant non-porous polymeric membranes. Permeation, solubility and diffusivity will be studied in the vicinity of the glass transition temperature to elucidate the changes in free volume that occur through this transition. Non-linear concentration gradients due to anisotropic swelling will be probed using novel laminated membrane systems. Water clustering wil ....The Permeation of Water through Industrial Membrane Systems. This project aims to understand the permeation of water through commercially relevant non-porous polymeric membranes. Permeation, solubility and diffusivity will be studied in the vicinity of the glass transition temperature to elucidate the changes in free volume that occur through this transition. Non-linear concentration gradients due to anisotropic swelling will be probed using novel laminated membrane systems. Water clustering will be evaluated by Fourier transform infrared spectroscopy and nuclear magnetic resonance. Results are proposed to be used to build a new phenomenological model of water permeation that can be used directly by engineers in the design of industrial membrane systems.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101215
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A novel pyrolysis process for high-quality bio-oil production from biomass. The project outcome will provide fundamental knowledge essential to the development of a novel pyrolysis process for high-quality bio-oil production with biochar, a value-added by-product. It will largely accelerate the commercialisation of the biomass pyrolysis process to reduce greenhouse gas emissions and fossil fuel use in the energy sector.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100230
Funder
Australian Research Council
Funding Amount
$160,000.00
Summary
Simultaneous measurements of reaction kinetics and particle distributions for cutting-edge research into CO2 storage, catalysis and novel materials. This integrated facility will support the development of new CO2 storage and utilisation technologies for Australia. It will also assist with developing technologies for corrosion protection, energy recovery from biomass, and mineral processing which will maintain the competitiveness of Australia in these industries.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100141
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Testing facilities for clean energy transformation technologies. As the world approaches peak oil production, the use of gasification to convert solid fuels to hydrogen and liquid fuels provides a low carbon footprint approach to the cleaner transformation of energy. This testing facility for clean energy transformation technologies will enhance the competitiveness of Australian science and engineering, contributing to the development of new technologies.
An innovative two-phase anaerobic process for biogas production from green waste and animal droppings for remote communities. Australia's remote communities, including agricultural and Indigenous communities, are an important part of Australian society and a significant contributor to the Australian economy, yet their access to cheap, secure, reliable and clean energy remains a significant challenge. Building on recent scientific advancement in anaerobic digestion, this project will develop a ne ....An innovative two-phase anaerobic process for biogas production from green waste and animal droppings for remote communities. Australia's remote communities, including agricultural and Indigenous communities, are an important part of Australian society and a significant contributor to the Australian economy, yet their access to cheap, secure, reliable and clean energy remains a significant challenge. Building on recent scientific advancement in anaerobic digestion, this project will develop a new technology for biogas production using locally available resources such as green waste and animal droppings. The outcome of this project will provide clean energy services to regional communities while minimising greenhouse gas emissions associated with waste disposal and thus contribute to the development of an environmentally sustainable Australia.Read moreRead less
Advanced biomass gasification process for distributed power generation with significant negative carbon emission in rural and regional Australia. The outcome of this project is fundamental knowledge essential to the development of advanced biomass gasification processes for distributed power generation with drastic reduction in carbon emissions and the recycling of inorganic nutrients to the land. It will contribute significantly to the future sustainability of rural and regional Australia.
Hierarchically structured carbon nanotube catalysts for the conversion of biomass to fuels and chemicals. Australia has significant biomass resources, which can be used to produce industrial chemicals and transport fuels. This project will develop a new family of carbon-nanotube-supported catalysts that will lead to improvements in process efficiency and performance for biofuels production.
Discovery Early Career Researcher Award - Grant ID: DE190100803
Funder
Australian Research Council
Funding Amount
$418,956.00
Summary
Single-enzyme membrane biofuel cells for wastewater and flue gas treatment. This project aims to mitigate energy and environmental problems by fusing the fields of membrane separation, biocatalysis and electrochemistry. The novel single-enzyme biofuel cells can generate electrical power from processes like wastewater micropollutant degradation and flue gas carbon dioxide conversion. However, the bottleneck is the lifetime of enzymes and the lack of efficient reactor design. This project expects ....Single-enzyme membrane biofuel cells for wastewater and flue gas treatment. This project aims to mitigate energy and environmental problems by fusing the fields of membrane separation, biocatalysis and electrochemistry. The novel single-enzyme biofuel cells can generate electrical power from processes like wastewater micropollutant degradation and flue gas carbon dioxide conversion. However, the bottleneck is the lifetime of enzymes and the lack of efficient reactor design. This project expects to overcome these challenges by developing metal-organic framework-based bioelectrode materials, and integrating them with separation membranes and single-enzyme fuel cells for energy generation. This project is expected to transform the current biocatalytic process for wastewater treatment and gas separation.Read moreRead less