Understanding the molecular structure and chemical behaviour of asphaltenes. This project will advance the science underpinning technologies for cost-effective use of heavy oil resources. Asphaltene aggregation and precipitation pose enormous challenges for extraction, transport, storage and refining of heavy oils. Understanding the physicochemical properties of asphaltenes is crucial to the future oil industry as light crudes become scarce. This project plans to develop and deploy an innovative ....Understanding the molecular structure and chemical behaviour of asphaltenes. This project will advance the science underpinning technologies for cost-effective use of heavy oil resources. Asphaltene aggregation and precipitation pose enormous challenges for extraction, transport, storage and refining of heavy oils. Understanding the physicochemical properties of asphaltenes is crucial to the future oil industry as light crudes become scarce. This project plans to develop and deploy an innovative molecular probe technique, combined with sequential thermal and solvent extraction and advanced tools for nanoscale characterisation, to reveal the molecular structure and chemical behaviour of asphaltenes. The resulting understanding of the mechanisms of asphaltene aggregation and dissociation may provide a scientific basis for controlling asphaltene precipitation to improve the stability and thus improve the use of heavy oils.Read moreRead less
Production, processing and combustion of an innovative slurry fuel for high efficiency distributed power generation. This project will advance the science underpinning the development of an innovative technology for energy production (with carbon capture) and use in remote regions. The outcomes of this research will help meet the great challenges of climate change and contribute to the development of an environmentally sustainable Australia.
Low-temperature plasma-catalytic conversion of CH4 and CO2 to alcohols. This project aims to investigate a novel concept of integrated low-temperature plasma and catalytic membrane hybrid reactor system for alcohols production from methane (CH4), carbon dioxide (CO2) and water vapour. This research will combine plasma physics and reaction engineering techniques to develop an innovative gas to liquid technology. The outcomes have the potential to transform the nation's natural gas industry, impro ....Low-temperature plasma-catalytic conversion of CH4 and CO2 to alcohols. This project aims to investigate a novel concept of integrated low-temperature plasma and catalytic membrane hybrid reactor system for alcohols production from methane (CH4), carbon dioxide (CO2) and water vapour. This research will combine plasma physics and reaction engineering techniques to develop an innovative gas to liquid technology. The outcomes have the potential to transform the nation's natural gas industry, improve energy efficiency, and utilise CO2 rich gas resources.Read moreRead less
Mechanisms of Ammonia (NH3) Combustion and Nitrogen Oxides (NOx) Formation. A mature commodity that can be readily made from renewable resources, ammonia (NH3) offers an environmentally sustainable and low-cost means of transition from fossil fuels to a clean, low-carbon and renewable energy future. The technical challenge is to combust NH3 efficiently with low nitrogen oxides (NOx) emissions. This project will advance the science of NH3 combustion and NOx formation. By applying innovative fixed ....Mechanisms of Ammonia (NH3) Combustion and Nitrogen Oxides (NOx) Formation. A mature commodity that can be readily made from renewable resources, ammonia (NH3) offers an environmentally sustainable and low-cost means of transition from fossil fuels to a clean, low-carbon and renewable energy future. The technical challenge is to combust NH3 efficiently with low nitrogen oxides (NOx) emissions. This project will advance the science of NH3 combustion and NOx formation. By applying innovative fixed-bed and fluidised-bed reactor techniques and kinetic modelling, the research will unravel fundamental characteristics and mechanisms of NH3 combustion, NOx formation and in-situ destruction that underpin the development and deployment of practical combustion systems for power generation using NH3 as a carbon-free fuel.Read moreRead less