Mapping, modelling, and manipulating graphene oxide interfaces. This project aims to provide a platform for the controllable manipulation of graphene oxide in water and with additives. Graphene oxide-based materials promise transformative change in the areas of filtration, separation science, energy materials and specialty coatings. Expansion of these materials into this broad range of high-performance applications is limited by the lack of reliable control over the organisation of the graphene ....Mapping, modelling, and manipulating graphene oxide interfaces. This project aims to provide a platform for the controllable manipulation of graphene oxide in water and with additives. Graphene oxide-based materials promise transformative change in the areas of filtration, separation science, energy materials and specialty coatings. Expansion of these materials into this broad range of high-performance applications is limited by the lack of reliable control over the organisation of the graphene oxide sheets in solution and in the presence of additives. This project will identify the practical steps for controlling the inter-sheet spacing in graphene oxide stacks, which is critical to realising their potential in real-world applications such as in filtration membranes for water desalination. This project will provide significant benefits in making reliable energy materials and filtration and separation membranes.Read moreRead less
Electrochemical biosensors for detection of cardiac disease markers in blood. Cardiovascular diseases leading to heart failure have a prevalence of over 16 per cent in Australia. The social, economic and health burden is higher than for any other disease group. Hence, it is critically important to develop fit-for-purpose sensors of known cardiac biomarkers, which alert patients and clinicians of the risk of imminent heart failure.
Engineering macromolecular architectures for targeted applications. The purpose of the project is to use intelligent design to synthesise highly complex polymer architectures for targeted applications. The advances of this research will be expanded to target ultrathin gas separation membranes, self-assembling star polymers for drug delivery and fluorinated macromonomers for in-vivo biodistribution studies.