Advanced Nanocomposites for Enhanced Containment of Hyper-Saline Leachate. This research project seeks to apply nanotechnology approaches to develop tailored materials that are green and cost-effective, which minimise groundwater contamination by hyper-saline industrial leachates and process waters. Australian industries will benefit from lower costs associated with storage, processing and reclamation of process waters, as well as from reduced environmental fines levied by the Environmental Prot ....Advanced Nanocomposites for Enhanced Containment of Hyper-Saline Leachate. This research project seeks to apply nanotechnology approaches to develop tailored materials that are green and cost-effective, which minimise groundwater contamination by hyper-saline industrial leachates and process waters. Australian industries will benefit from lower costs associated with storage, processing and reclamation of process waters, as well as from reduced environmental fines levied by the Environmental Protection Agency due to significantly reduced barrier failure and groundwater contaminations. Australian businesses involved in manufacture, design and construction of environmental barrier systems will have access to new materials and improved technology.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