pH Switching of Radical Reactivity and Orbital Conversion. Radicals are reactive species that have an unpaired electron, which is usually located in the highest occupied orbital. This proposal uses a combination of theory and experiment to design a new class of radical anions whose unpaired electron is not the highest occupied orbital, and whose electronic configuration reverts to the normal aufbau configuration upon protonation. These special radical anions will display unprecedented radical st ....pH Switching of Radical Reactivity and Orbital Conversion. Radicals are reactive species that have an unpaired electron, which is usually located in the highest occupied orbital. This proposal uses a combination of theory and experiment to design a new class of radical anions whose unpaired electron is not the highest occupied orbital, and whose electronic configuration reverts to the normal aufbau configuration upon protonation. These special radical anions will display unprecedented radical stability that is pH switchable, as well as ferromagnetism and conductivity upon oxidation. This project will exploit these unusual properties in the design of pH-switchable protecting groups for radicals for synthesis and polymerisation, and determine their role in oxidative stress and enzyme kinetics.Read moreRead less
Radicals in unconventional media - improving the sustainability of radical reactions through next generation ionic liquid radical chemistry. Despite significant advances over the past few decades, many free radical reactions are still carried out in organic solvents that are often toxic, flammable, difficult to recycle and employ undesirable reagents. It is timely that new free radical chemistry be developed that moves away from this "conventional" landscape. This proposal will develop a fundame ....Radicals in unconventional media - improving the sustainability of radical reactions through next generation ionic liquid radical chemistry. Despite significant advances over the past few decades, many free radical reactions are still carried out in organic solvents that are often toxic, flammable, difficult to recycle and employ undesirable reagents. It is timely that new free radical chemistry be developed that moves away from this "conventional" landscape. This proposal will develop a fundamental understanding of how free radicals interact with, and react in, (unconventional) ionic liquid solvents. This understanding will lead, in turn, to the development of new, more efficient, free radicals methods for the preparation of important materials that include biomolecules. Reduced environmental impact of free radical chemistry is the ultimate aim of this work.Read moreRead less
Shifting the trend in radical battery research . The project aims to address a growing problem of increasing energy consumption by storing intermittent energy from the sun in affordable and efficient flow batteries. The project expects to generate new knowledge in the areas of materials science and battery research by using innovative theoretical chemistry approaches to studying electrochemical properties of nitroxide radicals in ionic media. The project aims to develop radical organic flow batt ....Shifting the trend in radical battery research . The project aims to address a growing problem of increasing energy consumption by storing intermittent energy from the sun in affordable and efficient flow batteries. The project expects to generate new knowledge in the areas of materials science and battery research by using innovative theoretical chemistry approaches to studying electrochemical properties of nitroxide radicals in ionic media. The project aims to develop radical organic flow batteries by utilising ionic liquids to stabilise radicals. Intended outcomes of the project include improved efficiency of flow batteries that can store energy from widely used solar panels. This should provide significant benefits to Australia’s effort to switch to renewable energy technologies. Read moreRead less
Understanding and controlling the stereochemistry of free-radical polymerisation. The stereochemistry of a molecule, which relates to the relative spatial arrangement of its atoms, can have a profound effect on its physical and chemical properties. This project will use a computer-guided experimental approach to design new methods for controlling the stereochemistry of the polymers formed in free-radical polymerisation.
Controlling polymer microstructure with structured Lewis acids. Radical polymerisation is the most commercially important polymer process, favoured by industry for its broad scope and relatively low cost and environmental impact. However, its use in the synthesis of 'smart materials' for biomedical applications, molecular electronics and high-performance engineering applications has been hampered by the lack of microstructural control. This project aims to use a complementary combination of theo ....Controlling polymer microstructure with structured Lewis acids. Radical polymerisation is the most commercially important polymer process, favoured by industry for its broad scope and relatively low cost and environmental impact. However, its use in the synthesis of 'smart materials' for biomedical applications, molecular electronics and high-performance engineering applications has been hampered by the lack of microstructural control. This project aims to use a complementary combination of theory and experiment to develop novel structured Lewis acids for controlling the stereochemistry in free-radical polymerisation, and to utilise the recently discovered propagation catalysis conferred by simple Lewis acids to minimise defect structures and thereby improve the thermal and photostability of polymers.Read moreRead less