In situ microbial conversion of coal to methane: Biotechnology development for clean use of Australian coal. We will develop a biotechnology that uses native microorganisms to accelerate the underground conversion of coal to methane. Approximately 90% of Australia’s coal resources cannot be accessed economically using traditional mining technologies. A technology that converts coal to methane could generate an energy supply worth an estimated $60 billion, foster the development of an energy indu ....In situ microbial conversion of coal to methane: Biotechnology development for clean use of Australian coal. We will develop a biotechnology that uses native microorganisms to accelerate the underground conversion of coal to methane. Approximately 90% of Australia’s coal resources cannot be accessed economically using traditional mining technologies. A technology that converts coal to methane could generate an energy supply worth an estimated $60 billion, foster the development of an energy industry now in its infancy, and generate numerous new employment opportunities. Environmentally, methane is a cleaner burning fuel than coal, uses much less water for processing and generates the same quantity of electricity with lower CO2 emissions. This project highlights the fact that Australia’s microbial diversity is a resource we cannot afford to ignore.Read moreRead less
An assessment of carbon dioxide storage capacity of water bearing sedimentary basins. Dealing with the problems caused by climate change and global warming is among the greatest challenges facing Australia today. One of the approaches being considered to minimise anthropogenic influence over climate is the geo-sequestration of carbon dioxide (CO2). The proposed project will lead to greater understanding of storage capacity of sedimentary basins and identification of optimum injection conditions ....An assessment of carbon dioxide storage capacity of water bearing sedimentary basins. Dealing with the problems caused by climate change and global warming is among the greatest challenges facing Australia today. One of the approaches being considered to minimise anthropogenic influence over climate is the geo-sequestration of carbon dioxide (CO2). The proposed project will lead to greater understanding of storage capacity of sedimentary basins and identification of optimum injection conditions for geo-sequestration in such aquifers, and any potential mechanisms that could lead to migration of CO2 from the source rock back to the atmosphere.This will contribute to national efforts to reduce global warming, safeguard the Australian economy, and allow continued electricity generation from coal-fired plants.Read moreRead less
Influence of scale effect on the strength of rock mass for the better prediction of slope stability in large open-cut mines. The proposed project has the potential to bring national economic benefits through sustainable infrastructure and environment, commercial enterprise and community health and safety. Mining industry in Australia plays a major role for creating significant employment in regional Australia, coal-fired electricity generation, and export income which underpins the international ....Influence of scale effect on the strength of rock mass for the better prediction of slope stability in large open-cut mines. The proposed project has the potential to bring national economic benefits through sustainable infrastructure and environment, commercial enterprise and community health and safety. Mining industry in Australia plays a major role for creating significant employment in regional Australia, coal-fired electricity generation, and export income which underpins the international competitiveness of the entire Australian economy. The proposed project will assist Australian mining industry in gaining a better understanding of the mechanics of failure of large open cut mines, an improved design approach for high steep slopes, and in developing a new set of guidelines which can be used to assess such a risk. Read moreRead less
Model studies of multiphase flow in fluid bed reactors. Multiphase flow is widely encountered in mineral, metallurgical and chemical industries which are important components of Australia's economy. Understanding and modelling multiphase flow plays a significant role in the design, control and optimization of multiphase reactors in these industries. The success of this project will enhance computational multiphase flow capability and help build fluid bed reactors with high efficiency, low energy ....Model studies of multiphase flow in fluid bed reactors. Multiphase flow is widely encountered in mineral, metallurgical and chemical industries which are important components of Australia's economy. Understanding and modelling multiphase flow plays a significant role in the design, control and optimization of multiphase reactors in these industries. The success of this project will enhance computational multiphase flow capability and help build fluid bed reactors with high efficiency, low energy consumption and low emissions. The research outcomes will not only greatly benefit Australia's economy but also significantly help environmental protection beneficial to Australia's community.Read moreRead less