Nanomaterials: Probing supramolecular self-assembly at the solution/solid interface. Australia's competitiveness in nanotechnology must be underpinned by fundamental innovation and research. In a "bottom-up" approach to nanomaterials, it is important to understand, for the smallest possible machines that can be produced, how singular molecular components interact with one another, both during the assembly of any device and afterwards as it performs its function. For working devices the molecule ....Nanomaterials: Probing supramolecular self-assembly at the solution/solid interface. Australia's competitiveness in nanotechnology must be underpinned by fundamental innovation and research. In a "bottom-up" approach to nanomaterials, it is important to understand, for the smallest possible machines that can be produced, how singular molecular components interact with one another, both during the assembly of any device and afterwards as it performs its function. For working devices the molecules need to be assembled on a solid surface so that they can work in unison. In this project, in conjunction with researchers at the University of Cambridge, we use the new technique of gel-phase NMR spectroscopy to understand the factors involved as molecular components assemble on the surface of polystyrene beads.Read moreRead less
Maximizing solid state Nuclear Magnetic Resonance (NMR) with maximum entropy. Nuclear magnetic resonance is an essential technology for the characterisation of important industrial and biomedical molecules, molecular chains and complexes. This project aims to considerably expand the fundamental capability of experimental techniques for the study of materials in the solid state, in particular for a new class of biological nanoparticle. These advances will have important global implications for re ....Maximizing solid state Nuclear Magnetic Resonance (NMR) with maximum entropy. Nuclear magnetic resonance is an essential technology for the characterisation of important industrial and biomedical molecules, molecular chains and complexes. This project aims to considerably expand the fundamental capability of experimental techniques for the study of materials in the solid state, in particular for a new class of biological nanoparticle. These advances will have important global implications for research into life-saving therapeutic strategies aimed at many pharmaceutical targets embedded in cell membranes, protein misfolding disorders such as Alzheimer's disease and Huntington's disease, as well as development of the next generation of "green" plastics and other advanced polymers.Read moreRead less
Porphyrin Based Supramolecular Assemblies and Arrays III - Model Systems for the Construction of Photosynthetic Mimics and Devices. Solar cells that convert light to electricity are an excellent solution to bringing energy to remote locations with abundant sunlight. This research proposal aims to provide an intellectual grounding in the development of molecular systems and supramolecular arrays that are capable of such solar energy conversion (photovoltaics & artificial photosynthesis) or that ....Porphyrin Based Supramolecular Assemblies and Arrays III - Model Systems for the Construction of Photosynthetic Mimics and Devices. Solar cells that convert light to electricity are an excellent solution to bringing energy to remote locations with abundant sunlight. This research proposal aims to provide an intellectual grounding in the development of molecular systems and supramolecular arrays that are capable of such solar energy conversion (photovoltaics & artificial photosynthesis) or that have potential applications in photonics. Developments in this project may also lead to breakthroughs in areas such as nano-scale computing and cleaner and more sustainable energy productionRead moreRead less
Advanced framework materials for hydrogen storage applications. This project aims to develop new molecular materials capable of the highly efficient storage of hydrogen gas. Through an innovative interdisciplinary approach that targets the synthesis and detailed characterisation of two classes of molecular material this project expects to generate step-change advances in the understanding of how hydrogen gas uptake relates to the chemical and physical attributes of porous molecular systems. Sign ....Advanced framework materials for hydrogen storage applications. This project aims to develop new molecular materials capable of the highly efficient storage of hydrogen gas. Through an innovative interdisciplinary approach that targets the synthesis and detailed characterisation of two classes of molecular material this project expects to generate step-change advances in the understanding of how hydrogen gas uptake relates to the chemical and physical attributes of porous molecular systems. Significant anticipated outcomes and benefits include the development of new material design approaches that optimise performance across a diverse parameter space, and the generation of advanced new materials worthy of commercial development, spanning small scale mobile to large scale stationary storage applications.Read moreRead less
Porphyrin-Based Supramolecular Assemblies and Arrays II: Model Systems for the Construction of Photosynthetic Mimics and Devices. Solar cells that convert light to electricity are an excellent solution to bringing energy to remote locations with abundant sunlight. This research proposal aims to provide an intellectual grounding in the development of molecular systems and supramolecular arrays that are capable of such solar energy conversion (photovoltaics & artificial photosynthesis) or that ha ....Porphyrin-Based Supramolecular Assemblies and Arrays II: Model Systems for the Construction of Photosynthetic Mimics and Devices. Solar cells that convert light to electricity are an excellent solution to bringing energy to remote locations with abundant sunlight. This research proposal aims to provide an intellectual grounding in the development of molecular systems and supramolecular arrays that are capable of such solar energy conversion (photovoltaics & artificial photosynthesis) or that have potential applications in photonics. Developments in this project may also lead to breakthroughs in areas such as nano-scale computing and cleaner and more sustainable energy production.Read moreRead less
Towards Nano-Assembled Light Emitting Polymer Films. Advanced materials constructed with molecular level architecture through controlled nano-assembly will benefit medical science, biotechnology and nanotechnology, communications and the electronics fields. The national research priorities of nanotechnology and advanced materials through nano-assembly will be promoted by this work. This research will assist Australian industries to further advance these processes and devices leading to better qu ....Towards Nano-Assembled Light Emitting Polymer Films. Advanced materials constructed with molecular level architecture through controlled nano-assembly will benefit medical science, biotechnology and nanotechnology, communications and the electronics fields. The national research priorities of nanotechnology and advanced materials through nano-assembly will be promoted by this work. This research will assist Australian industries to further advance these processes and devices leading to better quality, cheaper, more efficient products. The Australian community will benefit through economic and technological advances. These advanced materials will promote health and environmental wellbeing.Read moreRead less
Construction and Use of Yoctowells as Vessels for Catalysis, Sensing and Artificial Photosynthesis. Yoctowell recognition systems are likely to form the basis of a new generation of biosensors, high throughput screening systems for identification of nucleotides and as energy transduction systems. As a result, this research will be relevant to technological advances in the areas of biotechnology and nanotechnology. Researching functional yoctowells containing photoactive and redox-active componen ....Construction and Use of Yoctowells as Vessels for Catalysis, Sensing and Artificial Photosynthesis. Yoctowell recognition systems are likely to form the basis of a new generation of biosensors, high throughput screening systems for identification of nucleotides and as energy transduction systems. As a result, this research will be relevant to technological advances in the areas of biotechnology and nanotechnology. Researching functional yoctowells containing photoactive and redox-active components will contribute to the major effort in basic research on smart optoelectric that are needed today to meet tomorrow's energy demands in a sustainable way. Read moreRead less
Dynamics of Photon-Induced Processes in Engineered Polymer Systems. This project will investigate photo-induced energy and electron transport in innovative polymer systems of well defined structure. New functionalised, aromatic and conjugated polymers will be synthesised and studied by ultrafast laser spectroscopic techniques. Information on the dynamics of light energy dissipation processes in these polymers on time-scales down to the femtosecond regime and at a single molecule level will be ....Dynamics of Photon-Induced Processes in Engineered Polymer Systems. This project will investigate photo-induced energy and electron transport in innovative polymer systems of well defined structure. New functionalised, aromatic and conjugated polymers will be synthesised and studied by ultrafast laser spectroscopic techniques. Information on the dynamics of light energy dissipation processes in these polymers on time-scales down to the femtosecond regime and at a single molecule level will be obtained. The results will provide the basic information required to develop novel photon-active materials and devices.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101627
Funder
Australian Research Council
Funding Amount
$447,625.00
Summary
Developing ultra adsorbent MOF composites as high performance materials. This project aims to improve the adsorption properties of porous materials through enhancing their selectivity and also creating new composites. This research expects to extend application opportunities to encompass real-life scenarios, in particular hydrogen transfer and carbon capture. Expected outcomes is the enhancement of the adsorbent properties of these porous materials, and an improvement of their selectivity and m ....Developing ultra adsorbent MOF composites as high performance materials. This project aims to improve the adsorption properties of porous materials through enhancing their selectivity and also creating new composites. This research expects to extend application opportunities to encompass real-life scenarios, in particular hydrogen transfer and carbon capture. Expected outcomes is the enhancement of the adsorbent properties of these porous materials, and an improvement of their selectivity and mechanical robustness. This is due to the synergistic strengthening effects of new graphene and nanodiamond composites. The benefit of this research is in bridging the gap between porous material synthesis and industrial application, contributing to Australia's becoming a world leader in clean energy research.Read moreRead less
X-ray snapshots of chemical transformations in open framework materials. The aim of this project is to unearth structural insights into the chemistry of coordinatively unsaturated metal complexes – reactive species lacking their full complement of binding groups – by isolating them within a carefully designed metal-organic framework and examining them via single crystal X-ray diffraction. Such intrinsically reactive species play an important role in metal-based catalysis, but their definitive st ....X-ray snapshots of chemical transformations in open framework materials. The aim of this project is to unearth structural insights into the chemistry of coordinatively unsaturated metal complexes – reactive species lacking their full complement of binding groups – by isolating them within a carefully designed metal-organic framework and examining them via single crystal X-ray diffraction. Such intrinsically reactive species play an important role in metal-based catalysis, but their definitive structural characterisation remains a significant challenge. This project aims to facilitate a detailed understanding of how these species bind and activate substrates and thus provide important first steps towards developing novel adsorbents for separations and efficient catalysts.Read moreRead less