Mathematical and Numerical Models of Piezoelectric Wave Energy Converters. The project will investigate piezoelectric wave energy converters. We will derive the equations of motion in a form suitable for use in marine engineering paradigms using variational methods and then solve these analytically and with smoothed particle hydrodynamics. Using these innovative techniques, this project will generate new knowledge capable of elucidating the multifaceted physical phenomena that occur when comple .... Mathematical and Numerical Models of Piezoelectric Wave Energy Converters. The project will investigate piezoelectric wave energy converters. We will derive the equations of motion in a form suitable for use in marine engineering paradigms using variational methods and then solve these analytically and with smoothed particle hydrodynamics. Using these innovative techniques, this project will generate new knowledge capable of elucidating the multifaceted physical phenomena that occur when complex fluid motion and deformable structures interact. The project outcomes include the development of mathematical and computation methods to handle intricate behaviours of piezoelectric elastic-fluids systems. These groundbreaking methods will allow these wave energy systems to be analysed and their effectiveness assessed.Read moreRead less
Advancing the chemistry of rare earths - an Australian resource. This project aims to advance knowledge of the synthesis, structures and reactivity of highly reactive rare earth metal-organic compounds. The project expects to build the knowledge and skills to underpin many developments of Australia's still under utilized rare earth resources to diversify from Chinese domination. The anticipated outcomes will be new synthetic and reaction chemistry including a demonstration of how size and electr ....Advancing the chemistry of rare earths - an Australian resource. This project aims to advance knowledge of the synthesis, structures and reactivity of highly reactive rare earth metal-organic compounds. The project expects to build the knowledge and skills to underpin many developments of Australia's still under utilized rare earth resources to diversify from Chinese domination. The anticipated outcomes will be new synthetic and reaction chemistry including a demonstration of how size and electronic factors can be used to modify and advance rare earth chemistry. This project should provide significant benefit such as are a better knowledge base in rare earth chemistry to underpin future applications in chemical manufacturing, new materials, catalysis and recycling.Read moreRead less
Mixing the jigsaw pieces of natural products: new molecules-new properties. This project aims to examine the capacity of exploiting the bacterial biosynthetic machinery to fast-track access to analogues of natural products. Due to increased drug resistance, new reservoirs of natural products are needed for evaluation as future drugs. Desferrioxamine B will be used as a model natural product to establish the biosynthesis of new analogues in bacterial culture supplemented with unsaturated, fluorin ....Mixing the jigsaw pieces of natural products: new molecules-new properties. This project aims to examine the capacity of exploiting the bacterial biosynthetic machinery to fast-track access to analogues of natural products. Due to increased drug resistance, new reservoirs of natural products are needed for evaluation as future drugs. Desferrioxamine B will be used as a model natural product to establish the biosynthesis of new analogues in bacterial culture supplemented with unsaturated, fluorinated or deuterated building blocks. The intended outcomes are to deliver advances in methods for generating structurally diverse pools of natural products, new label-free probes, knowledge of natural product biosynthesis, and excellence in training research students in frontier methods in chemical biology and drug discovery.Read moreRead less
Emergent organocopper complexes as robust catalysts for electrosynthesis. The capture and stabilisation of highly reactive chemical species is critical to making advances in the synthesis of novel materials, agrochemicals and pharmaceuticals. Metal-bound carbanions are essential components of carbon-carbon bond forming reactions. This project aims to develop an unprecedented family of copper catalysts and deliver an innovative and versatile chemical reactivity platform. Expected outcomes of this ....Emergent organocopper complexes as robust catalysts for electrosynthesis. The capture and stabilisation of highly reactive chemical species is critical to making advances in the synthesis of novel materials, agrochemicals and pharmaceuticals. Metal-bound carbanions are essential components of carbon-carbon bond forming reactions. This project aims to develop an unprecedented family of copper catalysts and deliver an innovative and versatile chemical reactivity platform. Expected outcomes of this project include methods of tempering and unleashing the high reactivity of these species by controlling the oxidation state of the copper ion. Benefits of these outcomes include fundamental understanding of the reactivity of a new class of copper complex that has potential commercial applications in catalysis.Read moreRead less
Metal complexes for sustainable light-driven synthesis. The aim of this project is to use cheap, abundant transition metal ions and visible light to enable challenging synthetic chemical reactions. The significant problems addressed are that most synthetic reactions using visible light currently require expensive precious metals, and fundamental reaction pathways used by Nature remain inaccessible. Both of these problems limit the scope of synthetic applications. The outcomes will be new knowled ....Metal complexes for sustainable light-driven synthesis. The aim of this project is to use cheap, abundant transition metal ions and visible light to enable challenging synthetic chemical reactions. The significant problems addressed are that most synthetic reactions using visible light currently require expensive precious metals, and fundamental reaction pathways used by Nature remain inaccessible. Both of these problems limit the scope of synthetic applications. The outcomes will be new knowledge and sustainable technologies that can better harness visible light for useful synthetic chemistry applications. The benefits will be more efficient and cost-effective routes to valuable molecules ubiquitous in everyday life.Read moreRead less
Investigating Energy Transfer Pathways in Lanthanoid Elements. This project aims to investigate fundamental aspects concerning the luminescent properties of compounds containing lanthanoid elements. These elements have extensive use in many high-tech applications, yet essential knowledge related to their properties is still quite limited. This project will elucidate in detail the origin of lanthanoid luminescence through a multidisciplinary approach combining synthetic chemistry and spectroscopy ....Investigating Energy Transfer Pathways in Lanthanoid Elements. This project aims to investigate fundamental aspects concerning the luminescent properties of compounds containing lanthanoid elements. These elements have extensive use in many high-tech applications, yet essential knowledge related to their properties is still quite limited. This project will elucidate in detail the origin of lanthanoid luminescence through a multidisciplinary approach combining synthetic chemistry and spectroscopy. The outcomes of this proposal will expand our limited knowledge in this field, underpinning the future development of novel materials for advanced applications. This will lead to significant economic benefit in Australia as new commercial applications relying on lanthanoid luminescence will be developed.Read moreRead less
Bioelectrochemical interconversion of the building blocks of life. This project aims to harness the efficiency of enzymes (Nature’s catalysts) by coupling them with an electrode for the electrochemical interconversion of carbon dioxide, carbon monoxide and formate; the organic building blocks of life. The significance of this research is that the efficient capture and reduction of carbon dioxide is an important quest in the environment and energy sectors. The expected outcomes of this project wi ....Bioelectrochemical interconversion of the building blocks of life. This project aims to harness the efficiency of enzymes (Nature’s catalysts) by coupling them with an electrode for the electrochemical interconversion of carbon dioxide, carbon monoxide and formate; the organic building blocks of life. The significance of this research is that the efficient capture and reduction of carbon dioxide is an important quest in the environment and energy sectors. The expected outcomes of this project will be an understanding of the reactivity of these enzymes and the conditions under which they may be utilised as part of a renewable electrochemical system. Benefits of this research should emerge in energy efficient technologies for generating fuels (formic acid) from waste products (carbon dioxide).Read moreRead less
Smart affinity membranes for manufacture of high value therapeutic proteins. This project aims to develop next generation separation membranes for production of high-value proteins from serum. Through a combination of innovative chemistries, biotechnology and engineering, the project will enhance production, efficiency and resolution of membranes for separating complex mixtures, thereby contributing to broader understanding in membrane science. By establishing a strong collaborative link between ....Smart affinity membranes for manufacture of high value therapeutic proteins. This project aims to develop next generation separation membranes for production of high-value proteins from serum. Through a combination of innovative chemistries, biotechnology and engineering, the project will enhance production, efficiency and resolution of membranes for separating complex mixtures, thereby contributing to broader understanding in membrane science. By establishing a strong collaborative link between academic and industry researchers, this project has the potential to significantly value-add to existing and exciting Australian technology by enhancing the efficiency of plasma fractionation, improving isolation of large molecules from complex media and by improving the downstream manufacturing and bioprocessing pipeline. Read moreRead less