Biochar as a renewable catalyst for hot gas cleaning. This project aims to generate new knowledge for the development of a novel hot gas cleaning technology. This project expects to understand the mechanisms of tar reforming using biochar as a renewable catalyst, which can avoid the problems associated with the catalyst deactivation and catalyst disposal if conventional supported catalysts are used. Expected outcomes of this project include a theoretical framework and a kinetic model describing ....Biochar as a renewable catalyst for hot gas cleaning. This project aims to generate new knowledge for the development of a novel hot gas cleaning technology. This project expects to understand the mechanisms of tar reforming using biochar as a renewable catalyst, which can avoid the problems associated with the catalyst deactivation and catalyst disposal if conventional supported catalysts are used. Expected outcomes of this project include a theoretical framework and a kinetic model describing the catalytic reforming of tar as part of the hot gas cleaning during the conversion of biomass. The technology will contribute to Australia’s improved energy security and reduced carbon dioxide (CO2) emissions in the carbon-constrained future.Read moreRead less
Smart self-propelled nanoreactors for catalytic environmental remediation. This project aims to develop nanomaterial design and technology to enable the applications of nanotechnology for environmental remediation. Various nanomotors with different asymmetric structures will be fabricated and tested for catalytic and photocatalytic degradation of aqueous pollutants. The physicochemical properties, motion behaviour and catalytic performance will be comprehensively investigated. The outcomes of th ....Smart self-propelled nanoreactors for catalytic environmental remediation. This project aims to develop nanomaterial design and technology to enable the applications of nanotechnology for environmental remediation. Various nanomotors with different asymmetric structures will be fabricated and tested for catalytic and photocatalytic degradation of aqueous pollutants. The physicochemical properties, motion behaviour and catalytic performance will be comprehensively investigated. The outcomes of the project will underpin the development of green technologies for sustainable energy conversion and water treatment. This will provide significant benefits, putting Australia in a leading position in the sustainable development of nanotechnology for sustainable energy supply and transformation as well as environmental and biomedical applications.Read moreRead less
Methanol to diesel. Australia has large remote gas reserves which are not accessible to markets via pipeline and cannot be effectively utilised using liquefied natural gas technology. Fischer-Tropsch conversion of gas to liquid (GTL), being capital intense, is uneconomical for these stranded gas resources. This project will develop a new GTL technology to produce sulphur-free, clean combustion diesel. The outcomes of this research will be a frontier technology that allows more effective utilisat ....Methanol to diesel. Australia has large remote gas reserves which are not accessible to markets via pipeline and cannot be effectively utilised using liquefied natural gas technology. Fischer-Tropsch conversion of gas to liquid (GTL), being capital intense, is uneconomical for these stranded gas resources. This project will develop a new GTL technology to produce sulphur-free, clean combustion diesel. The outcomes of this research will be a frontier technology that allows more effective utilisation of Australian remote gas resources to meet rising global demand for transport fuels, adding enormous value to Australian natural resources and contributing to Building and Transforming Australian industries.Read moreRead less
CO2 Utilisation for Energy Storage. This project aims to develop a novel technology that can convert carbon dioxide into useful products while storing intermittent renewable energy as green stable chemical energy. The project plans to focus on the development of a robust cathode for the conversion of carbon dioxide with optimum physical and chemical structure to achieve long-term stable performance. This technology would make a significant contribution to increasing the proportion of renewable e ....CO2 Utilisation for Energy Storage. This project aims to develop a novel technology that can convert carbon dioxide into useful products while storing intermittent renewable energy as green stable chemical energy. The project plans to focus on the development of a robust cathode for the conversion of carbon dioxide with optimum physical and chemical structure to achieve long-term stable performance. This technology would make a significant contribution to increasing the proportion of renewable energy in our energy supply and reducing our carbon dioxide emissions.Read moreRead less
Integrated photo and thermal catalysis for economic carbon dioxide conversion to fuels. The project aims to develop an integrated process for simultaneously photo- and thermal-catalytic conversion of carbon dioxide and water vapour to hydrocarbon fuels and chemicals using solar light and waste heat from flue gas. This project will design and make multi-functional catalysts based on zirconium metal organic frameworks, incorporating quantum dots and metal nanoclusters. This project is expected to ....Integrated photo and thermal catalysis for economic carbon dioxide conversion to fuels. The project aims to develop an integrated process for simultaneously photo- and thermal-catalytic conversion of carbon dioxide and water vapour to hydrocarbon fuels and chemicals using solar light and waste heat from flue gas. This project will design and make multi-functional catalysts based on zirconium metal organic frameworks, incorporating quantum dots and metal nanoclusters. This project is expected to develop an advanced materials system, reduce carbon dioxide and use it to produce fuel, and harness solar energy. The project should advance Australia’s leading role in reducing carbon emission, and producing clean energy and nanotechnology.Read moreRead less
Highly efficient electric power and value-added synthesis gas co-generation from methane with zero greenhouse gas emission. This project addresses a novel sealing-free solid oxide fuel cell system producing simultaneously synthesis gas and electricity from methane with zero greenhouse gas emission. The project aims to deliver economic benefits and contribute to environmental protection and increased employment opportunities.
Structurally designed catalysts for high-performance natural gas reforming. This project aims to develop a new class of highly stable catalysts with specially designed physical and chemical structures that can be used in high temperature chemical processes. These catalysts can potentially be used for the reforming of natural gas to produce the synthesis gas, which can then be used to produce liquid fuels and chemicals.
Experimental and modelling development of advanced symmetrical fuel cells. Fuel cells are advanced energy conversion devices with high efficiency and low emissions. The overall goal of this project is to increase the competitiveness of the fuel cell technology with currently matured power generation technologies based on fossil fuel combustion through innovations. Both experimental development and modelling studies will be performed. It is expected that: reduced materials, fabrication and mainte ....Experimental and modelling development of advanced symmetrical fuel cells. Fuel cells are advanced energy conversion devices with high efficiency and low emissions. The overall goal of this project is to increase the competitiveness of the fuel cell technology with currently matured power generation technologies based on fossil fuel combustion through innovations. Both experimental development and modelling studies will be performed. It is expected that: reduced materials, fabrication and maintenance costs; improved performance; increased coking resistance and sulfur tolerance; and prolonged lifetime of solid oxide fuel cells will be achieved. This project endeavours to advance the field of electrochemical energy conversion. It is also expected to expand the science and engineering knowledge base and pave the way to sustainable energy systems.Read moreRead less
In-situ catalytic upgrading of bio-oil using scrap tyre char. This project aims to develop advanced, cost-competitive catalysts based on scrap tyre char, an otherwise low-value by-product. These catalysts will be optimised for use in upgrading bio-oil derived from the pyrolysis of woody eucalyptus, an abundant biomass resource across Australia. The project is expected to promote the commercialisation of bio-oil production and enhance the valorisation of scrap tyre char. This is expected to reduc ....In-situ catalytic upgrading of bio-oil using scrap tyre char. This project aims to develop advanced, cost-competitive catalysts based on scrap tyre char, an otherwise low-value by-product. These catalysts will be optimised for use in upgrading bio-oil derived from the pyrolysis of woody eucalyptus, an abundant biomass resource across Australia. The project is expected to promote the commercialisation of bio-oil production and enhance the valorisation of scrap tyre char. This is expected to reduce the carbon footprint from Australian industry, and promote the recycling and reuse of waste scrap tyres.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC200100023
Funder
Australian Research Council
Funding Amount
$4,920,490.00
Summary
ARC Training Centre for The Global Hydrogen Economy. The centre aims to transform Australia into a hydrogen powerhouse by building enabling capacity in hydrogen innovation in a short timeframe. Australia is well-positioned to capitalise on the emerging global growth of hydrogen, however to be competitive and produce at scale, we need cost-effective hydrogen technologies and capabilities for transitioning hydrogen into industries. This innovative, five-year program will generate new technologies ....ARC Training Centre for The Global Hydrogen Economy. The centre aims to transform Australia into a hydrogen powerhouse by building enabling capacity in hydrogen innovation in a short timeframe. Australia is well-positioned to capitalise on the emerging global growth of hydrogen, however to be competitive and produce at scale, we need cost-effective hydrogen technologies and capabilities for transitioning hydrogen into industries. This innovative, five-year program will generate new technologies and equip a future workforce of industry-focused engineers with advanced skills for development and scaling-up of hydrogen generation and transport. Benefits include: export of hydrogen fuel and advanced technologies; job creation; and a lower emissions domestic energy industry.Read moreRead less