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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
Mixed valence coordination polymers and their electronic properties. The project aims to synthesise and examine the properties of crystalline coordination polymers that exhibit unusual and technologically useful properties arising from long-range electronic communication. The focus will be on materials in which the modular components (ligands, metals and counterions) are present in mixed valence states. The experimental investigation will be supported by dispersion-corrected, periodic-boundary D ....Mixed valence coordination polymers and their electronic properties. The project aims to synthesise and examine the properties of crystalline coordination polymers that exhibit unusual and technologically useful properties arising from long-range electronic communication. The focus will be on materials in which the modular components (ligands, metals and counterions) are present in mixed valence states. The experimental investigation will be supported by dispersion-corrected, periodic-boundary DFT calculations which will be employed to both rationalise behaviour and provide direction for the generation of new materials.Read moreRead less
New molecular architectures: synthesis, structure and properties. Through the implementation of rational design principles we intend to generate new types of nanoporous materials by bringing together molecular building blocks of appropriate size, shape and functionality. With such systems able to act as hosts for small molecules we expect that novel and technologically useful properties will arise.
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
Precision luminescent solar concentrators from robust quantum dot arrays. Precision luminescent solar concentrators from robust quantum dot arrays. This project aims to make luminescent solar concentrators that can harness solar energy from surfaces not suited for conventional solar cells, such as car windows. It will design, synthesise and conduct detailed energy transfer studies of robust inorganic quantum dot arrays with fit-for-purpose precise spectral properties. Synthetic light-harvesting ....Precision luminescent solar concentrators from robust quantum dot arrays. Precision luminescent solar concentrators from robust quantum dot arrays. This project aims to make luminescent solar concentrators that can harness solar energy from surfaces not suited for conventional solar cells, such as car windows. It will design, synthesise and conduct detailed energy transfer studies of robust inorganic quantum dot arrays with fit-for-purpose precise spectral properties. Synthetic light-harvesting dye arrays have often been proposed to solve bottleneck challenges in the solar energy sector but there are issues with stability, processing and their photophysical output matching market needs. This project’s dyes are expected to create market opportunities for Australian luminescent solar concentrator technology.Read moreRead less
Switchable molecules for molecular nanoscience. This project targets the development and exploration of switchable molecules for future nanoscale devices. Applications will include individual molecules as: units of magnetic memory for high density data storage, quantum bits in quantum computers, components in electronic devices and switching units in display media.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100131
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Laser facility for ultra-sensitive molecular characterisation. Lasers are indispensable tools for the characterization and photochemical modification of molecular systems. Powerful lasers produce intense bursts of light across the electromagnetic spectrum, from the infrared to the ultraviolet. This versatility allows chemists to observe the dynamical behaviour of single molecules on ultra-fast timescales, to probe the shape of molecules relevant to the action of therapeutic drugs, to explore the ....Laser facility for ultra-sensitive molecular characterisation. Lasers are indispensable tools for the characterization and photochemical modification of molecular systems. Powerful lasers produce intense bursts of light across the electromagnetic spectrum, from the infrared to the ultraviolet. This versatility allows chemists to observe the dynamical behaviour of single molecules on ultra-fast timescales, to probe the shape of molecules relevant to the action of therapeutic drugs, to explore the characteristics of molecules found in space, and to initiate laser-activated chemical processes in microscopic dimensions to modify sensor surfaces. The proposed laser facility will enable progress in these areas and will help maintain Australia's research edge in nanotechnology and biotechnology.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100144
Funder
Australian Research Council
Funding Amount
$480,000.00
Summary
Advanced X-ray facility for structural elucidation and photocrystallography. This project aims to establish an advanced photocrystallography X-ray facility. Accurately determining molecular structure and understanding how molecules interact with light is important to design and optimise new materials. Normally, measurements to elucidate these properties have to be done separately, making structure-property correlations difficult. The facility will allow the creation of new materials with applica ....Advanced X-ray facility for structural elucidation and photocrystallography. This project aims to establish an advanced photocrystallography X-ray facility. Accurately determining molecular structure and understanding how molecules interact with light is important to design and optimise new materials. Normally, measurements to elucidate these properties have to be done separately, making structure-property correlations difficult. The facility will allow the creation of new materials with application in pharmaceuticals, separation science, organic optoelectronics and magnetic materials. The facility will build capacity in X-ray techniques, create collaborations and provide a unique training ground for students and Early Career Researchers. The advances in materials innovation will strengthen the future viability of Australian industries and manufacturing innovation.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).