The role of water uptake in novel all solid-state polymeric ion sensors. This research will enable the development of robust all solid-state polymeric ion sensors based on unplasticized copolymers. Significantly, the physical and chemical robustness of these copolymer ion sensors will allow their widespread use in new and exciting analytical applications, e.g., in-situ analysis of environmental samples in submersible instruments, clinical analysis of whole blood, in-vivo use of miniaturized ele ....The role of water uptake in novel all solid-state polymeric ion sensors. This research will enable the development of robust all solid-state polymeric ion sensors based on unplasticized copolymers. Significantly, the physical and chemical robustness of these copolymer ion sensors will allow their widespread use in new and exciting analytical applications, e.g., in-situ analysis of environmental samples in submersible instruments, clinical analysis of whole blood, in-vivo use of miniaturized electrodes in biological media, especially single cells and minute samples in biology and forensic science, etc. Extensive use of neutron characterization techniques aligns strongly this project with the new OPAL reactor to be commissioned in 2007.Read moreRead less
Probing the internal contacts of all solid-state polymeric ion sensors. The results of this research will enable the development of robust and reliable all solid-state polymeric ion sensors. These sensors will enable solutions to significant environmental problems such as soil salinity and acidity, and may pave the way for new and exciting analytical applications, e.g., miniaturized implantable sensors for in-vivo use, microfluidics and Forensic Science, single blood droplet clinical analyzers, ....Probing the internal contacts of all solid-state polymeric ion sensors. The results of this research will enable the development of robust and reliable all solid-state polymeric ion sensors. These sensors will enable solutions to significant environmental problems such as soil salinity and acidity, and may pave the way for new and exciting analytical applications, e.g., miniaturized implantable sensors for in-vivo use, microfluidics and Forensic Science, single blood droplet clinical analyzers, rugged solid contact ion sensors for use in submersible oceanographic analyzers, etc. The research will develop a unique in-situ neutron reflectometry technique for the study of electrochemical interfaces, providing scientific opportunities for the new Australian Replacement Research Reactor.Read moreRead less
Probing the interfaces of electrochemical sensors. The nanostructured surfaces of electrochemical sensors for iron, mercury and cadmium will be characterised by using a range of state-of-the-art surface analysis techniques. Whilst electrochemical sensors are extremely valuable in monitoring of trace metals in the aquatic environment, a knowledge of the surface chemical physics of the systems is vital in order to widen their use in analytical/environmental chemistry. This project will derive a u ....Probing the interfaces of electrochemical sensors. The nanostructured surfaces of electrochemical sensors for iron, mercury and cadmium will be characterised by using a range of state-of-the-art surface analysis techniques. Whilst electrochemical sensors are extremely valuable in monitoring of trace metals in the aquatic environment, a knowledge of the surface chemical physics of the systems is vital in order to widen their use in analytical/environmental chemistry. This project will derive a universal model for the surface chemistry and physics of electrochemical sensors, enabling environmental scientists to develop unique sensor methods for studying the speciation of environmentally important trace metals such as those mentioned above.Read moreRead less
Overcoming the Barriers in the Development of Solid State Materials. A major impact of this proposal shall be in terms of researcher training. By synergistically combining materials chemistry, fundamental physical chemistry, inorganic chemistry, and electrochemistry, this basic program will provide high level training to a new generation of Australian and Irish scientists thus helping to safeguard the economic competitiveness of the countries. Beyond the impact of the fundamental insight into t ....Overcoming the Barriers in the Development of Solid State Materials. A major impact of this proposal shall be in terms of researcher training. By synergistically combining materials chemistry, fundamental physical chemistry, inorganic chemistry, and electrochemistry, this basic program will provide high level training to a new generation of Australian and Irish scientists thus helping to safeguard the economic competitiveness of the countries. Beyond the impact of the fundamental insight into the rational design, structure and behaviour of a new class of solid materials, success in this program will have widespread applications for a variety of strategically important industries and should place Australia and Ireland at the forefront of this technologyRead moreRead less
Ionic Liquids and Solids - New Designs, Insights and Applications. Ionic Materials in the form of liquid salts and plastic crystals are of interest in a wide range of applications including environmentally benign synthesis of chemicals and high stability electrolytes for batteries, capacitors and other devices. These materials represent some of the most stable chemicals known, making them attractive for any application where complete stability and recycling are issues. Building on our recent wor ....Ionic Liquids and Solids - New Designs, Insights and Applications. Ionic Materials in the form of liquid salts and plastic crystals are of interest in a wide range of applications including environmentally benign synthesis of chemicals and high stability electrolytes for batteries, capacitors and other devices. These materials represent some of the most stable chemicals known, making them attractive for any application where complete stability and recycling are issues. Building on our recent work, this project will design, prepare and characterize novel materials of this type for a number of target applications. Collaborators in Europe and USA will be involved in the analysis and testing of the materials.Read moreRead less
Low viscosity, high ionic conductivity ionic liquids for lithium metal batteries. Current consumer electronic devices rely on lithium-ion batteries to provide a high energy density power source. There are growing safety concerns about the electrolytes in these devices after recent incidents involving fires in mobile phones. Recent advances in ionic liquids (ILs) have seen the development of new electrolytes for such devices, with enhanced physical properties that offer major safety advantages. H ....Low viscosity, high ionic conductivity ionic liquids for lithium metal batteries. Current consumer electronic devices rely on lithium-ion batteries to provide a high energy density power source. There are growing safety concerns about the electrolytes in these devices after recent incidents involving fires in mobile phones. Recent advances in ionic liquids (ILs) have seen the development of new electrolytes for such devices, with enhanced physical properties that offer major safety advantages. However, the viscosity of these materials currently limit their capabilities. New IL materials to be developed in this project will pave the way for the development of safer devices and new sustainable energy industries in Australia.Read moreRead less
Advanced Molecular Frameworks for Sodium Battery Electrode Applications. This project aims to develop new molecular materials capable of high capacity sodium-ion insertion. Through an innovative interdisciplinary approach that targets the synthesis and detailed characterisation of an extensive family of materials this project expects to generate major advances in the understanding of how the chemical, physical and structural attributes of the materials relate to their electrical charge/discharge ....Advanced Molecular Frameworks for Sodium Battery Electrode Applications. This project aims to develop new molecular materials capable of high capacity sodium-ion insertion. Through an innovative interdisciplinary approach that targets the synthesis and detailed characterisation of an extensive family of materials this project expects to generate major advances in the understanding of how the chemical, physical and structural attributes of the materials relate to their electrical charge/discharge behaviours. Significant anticipated outcomes and benefits include the development of new material design approaches that optimise battery electrode performance across a diverse parameter space, and the generation of advanced new materials worthy of commercial development in low-cost, large-scale battery applications.Read moreRead less
Better Batteries via Controlling the Properties of Electrolytic Manganese Dioxide. Physical properties of electrolytic manganese dioxide (EMD) such as crystal structure, morphology and electrochemical characteristics determine its usefulness in alkaline batteries. However, the relationship between these parameters is not well understood. This APAI project will attempt to address these shortcomings in the current understanding of the production process by focussing on the relationships between fu ....Better Batteries via Controlling the Properties of Electrolytic Manganese Dioxide. Physical properties of electrolytic manganese dioxide (EMD) such as crystal structure, morphology and electrochemical characteristics determine its usefulness in alkaline batteries. However, the relationship between these parameters is not well understood. This APAI project will attempt to address these shortcomings in the current understanding of the production process by focussing on the relationships between fundamental physical, chemical and electrochemical properties of EMD. The results will be of benefit in optimising the process and ensuring that EMD with superior performance can be consistently produced.Read moreRead less
Artificial photosynthesis for solar fuel production. We aim to realise an artificial system that converts solar energy to hydrogen (artificial photosynthesis). The resulting device will be able to 'split' water into oxygen and hydrogen, whereas hydrogen can be further converted into electricity or heat (combustion).
Polyaniline Nanofibre Systems. Advanced materials such as the conducting polymer and applications of these materials at the nanoscale and up is clearly a cutting edge area of international interest. Development of readily processable nano systems has been a challenge with a clear scientific and commercial benefit. This proposal will bring linkages to Australia with the world leader in the field, Professor Kaner -UCLA, on the synthesis of polyaniline nanofibres and associated photowelding process ....Polyaniline Nanofibre Systems. Advanced materials such as the conducting polymer and applications of these materials at the nanoscale and up is clearly a cutting edge area of international interest. Development of readily processable nano systems has been a challenge with a clear scientific and commercial benefit. This proposal will bring linkages to Australia with the world leader in the field, Professor Kaner -UCLA, on the synthesis of polyaniline nanofibres and associated photowelding processes. The opportunities to Australia and the USA will be to expand the potential utility of such systems, which without such interactions would permit others to take a stake hold in this emergent and potentially lucrative technology.Read moreRead less