Data-driven monitoring of raceway dynamics in ironmaking blast furnaces. Raceway dynamics in ironmaking blast furnaces affect operational stability and cost considerably, yet their dynamic behaviour has not been well monitored online. The project aims to develop a data-driven model for monitoring the internal state of gas-solid-powder reacting flow in the raceway and predicting raceway anomalies online. It will be achieved by combining particle-fluid numerical simulations with data processing an ....Data-driven monitoring of raceway dynamics in ironmaking blast furnaces. Raceway dynamics in ironmaking blast furnaces affect operational stability and cost considerably, yet their dynamic behaviour has not been well monitored online. The project aims to develop a data-driven model for monitoring the internal state of gas-solid-powder reacting flow in the raceway and predicting raceway anomalies online. It will be achieved by combining particle-fluid numerical simulations with data processing and reduced-order state observer, supported by lab/plant experiments, and collaborating with two industry partners from coal and steel industries. The project outcomes including codes, models and raceway control strategies can help promote Australian metallurgical coal's global markets and ultimately the Australian economy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101666
Funder
Australian Research Council
Funding Amount
$395,588.00
Summary
Engineering nanoparticles with enhanced adhesion at the nano-bio interfaces. This project aims to develop a next-generation adhesive nanoparticle platform through in-depth understandings of nanoparticle interactions with bio-interfaces. This project expects to generate new knowledge in the multidisciplinary research field at nano-bio-interfaces by using a recently developed nano-colloidal probe technology, instructing the rational design of nanoparticles with enhanced interface adhesive properti ....Engineering nanoparticles with enhanced adhesion at the nano-bio interfaces. This project aims to develop a next-generation adhesive nanoparticle platform through in-depth understandings of nanoparticle interactions with bio-interfaces. This project expects to generate new knowledge in the multidisciplinary research field at nano-bio-interfaces by using a recently developed nano-colloidal probe technology, instructing the rational design of nanoparticles with enhanced interface adhesive properties. Expected outcomes include a family of adhesive nanoparticles designed for nanopesticide and animal feed applications, with the potential to deliver valuable intellectual property of commercial interest and economic benefit through technology advancement.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101030
Funder
Australian Research Council
Funding Amount
$368,446.00
Summary
Monoatomic metal doping of carbon-based nanomaterials for hydrogen storage. This project aims to present a new concept of monoatomic metal doped carbon-based nanomaterials as advanced solid-state hydrogen storage materials (S-HSMs) for hydrogen fuel cells. The key feature for this synthesis is the use of the unique “defect” structures in carbon lattice as the efficient anchoring sites to immobilise the metal species at atomic level. This project is expected to create new knowledge of atomic inte ....Monoatomic metal doping of carbon-based nanomaterials for hydrogen storage. This project aims to present a new concept of monoatomic metal doped carbon-based nanomaterials as advanced solid-state hydrogen storage materials (S-HSMs) for hydrogen fuel cells. The key feature for this synthesis is the use of the unique “defect” structures in carbon lattice as the efficient anchoring sites to immobilise the metal species at atomic level. This project is expected to create new knowledge of atomic interface catalysis and develop practical applications of S-HSMs in storage tanks for fuel cells, leading to reduction of carbon dioxide emissions and alleviation of air pollution. The success of this project will greatly enhance the Australian clean energy industries.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH230100010
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Research Hub for Smart Process Design and Control . ARC Research Hub for Smart Process Design and Control aims to develop and apply advanced computational technologies to model and optimise complex multiphase processes by integrating the novel multiscale and AI modelling approaches. The outcomes include theories, computer models and simulation techniques, advanced knowledge about process modelling and optimisation, innovative technologies and processes for low carbon operations, and tens of ....ARC Research Hub for Smart Process Design and Control . ARC Research Hub for Smart Process Design and Control aims to develop and apply advanced computational technologies to model and optimise complex multiphase processes by integrating the novel multiscale and AI modelling approaches. The outcomes include theories, computer models and simulation techniques, advanced knowledge about process modelling and optimisation, innovative technologies and processes for low carbon operations, and tens of postdoc and PhD students through academic, industrial and international collaboration. Their application will significantly improve energy/process efficiency and reduce CO2 emission. The Hub will generate a significant impact on the mineral and metallurgical industries which are important to Australia.Read moreRead less
Low emission iron and steelmaking using hydrogen to pre-reduce lump ore. This project aims to develop and apply a new route of lump iron ore pre-reduction with hydrogen or H2-enriched gases for ironmaking to minimise CO2 emission from steel production. The route will be built up on the base of H2 reduction kinetics of iron ore and with novel technologies such as CO2 recycle and H2-heating using hot blast, underpinning the hydrogen economy by addressing the environmental concerns in mineral and s ....Low emission iron and steelmaking using hydrogen to pre-reduce lump ore. This project aims to develop and apply a new route of lump iron ore pre-reduction with hydrogen or H2-enriched gases for ironmaking to minimise CO2 emission from steel production. The route will be built up on the base of H2 reduction kinetics of iron ore and with novel technologies such as CO2 recycle and H2-heating using hot blast, underpinning the hydrogen economy by addressing the environmental concerns in mineral and steel industries. It is not only significant for low-carbon steel production, but also for better fundamental understanding to develop the future zero-emission iron and steelmaking with hydrogen. The project will be very beneficent because it increases the use of lump iron ore and expends Australian export of iron ores.Read moreRead less
Biomass-derived Carbon Dots Enable Flexible, On-Demand Hydrogen Delivery . Methanol is a promising liquid hydrogen carrier for long distance H2 transportation and exportation, because it is rich in hydrogen content, cheap, recyclable between methanol-formaldehyde and easier to manufacture from renewable resources including biomass waste. The critical bottleneck in adopting methanol as the carrier is the demanding dehydrogenation process. The project aims to create a new class of photocatalyst ba ....Biomass-derived Carbon Dots Enable Flexible, On-Demand Hydrogen Delivery . Methanol is a promising liquid hydrogen carrier for long distance H2 transportation and exportation, because it is rich in hydrogen content, cheap, recyclable between methanol-formaldehyde and easier to manufacture from renewable resources including biomass waste. The critical bottleneck in adopting methanol as the carrier is the demanding dehydrogenation process. The project aims to create a new class of photocatalyst based on biomass-derived carbon nanodots grown on transition metal (di)chalcogenide nanosheets that can effectively enable a light-controlled methanol H2 release of desired quantity. The key outcomes will be a new class of photocatalysts and flexible, on-demand hydrogen delivery technology for liquid hydrogen carriers.Read moreRead less
Nanoengineered, Encapsulated Catalysts from Fly Ash Waste. This project aims to deliver advanced catalysts and novel catalyst synthesis methods from the use of iron-rich fly ash, an otherwise abundant valueless waste with projected steady growth across Australia and globally. The as-synthesised catalysts are expected to be applicable to and exhibit excellent activity in the production of green hydrogen and renewable bio-fuels from lignocellulosic waste. These efforts are significant and benefici ....Nanoengineered, Encapsulated Catalysts from Fly Ash Waste. This project aims to deliver advanced catalysts and novel catalyst synthesis methods from the use of iron-rich fly ash, an otherwise abundant valueless waste with projected steady growth across Australia and globally. The as-synthesised catalysts are expected to be applicable to and exhibit excellent activity in the production of green hydrogen and renewable bio-fuels from lignocellulosic waste. These efforts are significant and beneficial in restoring the manufacturing capability of Australian industry, driving Australian industry towards the development of a circular economy for the appropriate management of solid waste, as well as for a seamless introduction of renewable and clean energy sources to address the pressing climate change.Read moreRead less
Depressing pyrrhotite in copper and gold flotation. The mining industry is processing low-grade ores associated with high amounts of waste minerals. Extracting metals from low-grade ores is very difficult with technical challenges in rejecting waste minerals. This project aims to understand the surface properties and the behaviour of a major waste mineral which is becoming increasingly problematic during the processing of copper and gold ores. New chemistry and chemical reagents will be develope ....Depressing pyrrhotite in copper and gold flotation. The mining industry is processing low-grade ores associated with high amounts of waste minerals. Extracting metals from low-grade ores is very difficult with technical challenges in rejecting waste minerals. This project aims to understand the surface properties and the behaviour of a major waste mineral which is becoming increasingly problematic during the processing of copper and gold ores. New chemistry and chemical reagents will be developed to efficiently and economically reject the waste mineral by manipulating the reactions that take place on its surface. This project expects to have immediate economic and environmental impacts through increasing metal production, cutting greenhouse gas emissions and applying new green reagents.Read moreRead less
Converging on new particles and fundamental symmetries. The goal of this project is to test theories for new particles and fundamental symmetries. By using advanced computational and statistical methods to combine all relevant data from many different experiments with a large number of different theoretical predictions, it expects to reveal just how well different theories actually describe reality. This will help us to understand what new particles and fundamental symmetries exist beyond thos ....Converging on new particles and fundamental symmetries. The goal of this project is to test theories for new particles and fundamental symmetries. By using advanced computational and statistical methods to combine all relevant data from many different experiments with a large number of different theoretical predictions, it expects to reveal just how well different theories actually describe reality. This will help us to understand what new particles and fundamental symmetries exist beyond those we already know. It will lead to new algorithms and computational methods in machine learning and statistical sampling, and will train a cohort of graduates highly skilled in statistical data science and research computing.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101026
Funder
Australian Research Council
Funding Amount
$438,835.00
Summary
Atomic physics as a probe for fundamental physics and dark matter. The Standard Model is extremely effective at describing the fundamental particles and interactions, but is known to be incomplete. This project aims to uncover new signatures of physics beyond the Standard Model that may be observed in atomic experiments. This project expects to generate new knowledge to help unravel the mystery of dark matter, which accounts for the majority (85%) of the matter in the universe. Expected outcomes ....Atomic physics as a probe for fundamental physics and dark matter. The Standard Model is extremely effective at describing the fundamental particles and interactions, but is known to be incomplete. This project aims to uncover new signatures of physics beyond the Standard Model that may be observed in atomic experiments. This project expects to generate new knowledge to help unravel the mystery of dark matter, which accounts for the majority (85%) of the matter in the universe. Expected outcomes include extending theoretical atomic physics methods, calculating new observable atomic effects, and combining these with experiments to probe fundamental physics and search for dark matter. These outcomes would contribute to the expanding knowledge in the fields of atomic and fundamental physics.Read moreRead less