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Advanced adsorbents for gas separations. Efficient purification of natural gas and separation of similarly-sized molecules in gas mixtures is increasingly important in our drive to develop a more sustainable way of living in an energy-constrained world. This project will develop a new class of adsorbents to deliver a level of separation efficiency much higher than that currently in use.
ARC Centre of Excellence in Exciton Science. This Centre aims to manipulate the way light energy is absorbed, transported and transformed in advanced molecular materials. The research programme spans high-throughput computational screening, single molecule photochemistry and ultrafast spectroscopy and embraces innovative outreach and commercial translation activities. The Centre plans to capture the knowledge generated as new intellectual property, materials processing know-how, and through the ....ARC Centre of Excellence in Exciton Science. This Centre aims to manipulate the way light energy is absorbed, transported and transformed in advanced molecular materials. The research programme spans high-throughput computational screening, single molecule photochemistry and ultrafast spectroscopy and embraces innovative outreach and commercial translation activities. The Centre plans to capture the knowledge generated as new intellectual property, materials processing know-how, and through the creation of new employment opportunities. The expected outcomes and benefits include new Australian technologies in solar energy conversion, energy-efficient lighting and displays, security labelling and optical sensor platforms for defence.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL120100019
Funder
Australian Research Council
Funding Amount
$2,879,582.00
Summary
Protonic materials for green chemical futures. By emulating the structures that nature has evolved this project will create novel materials that will be used to develop new sustainable chemical technologies. Working with local and international collaborators, outcomes will include new approaches to the conversion of carbon dioxide into valuable chemicals and for renewable energy generation and storage.
Data-driven development of photocatalytic and optoelectronic perovskites. This project aims to use materials informatics to discover new, high efficiency perovskites for synthesis and testing in optoelectronic applications. This project expects to identify perovskite composition-property relationships to overcome current drawbacks of high performance perovskites (contain rare or toxic elements and low stability in oxidative and humid environments) by considered selection of elements and their pr ....Data-driven development of photocatalytic and optoelectronic perovskites. This project aims to use materials informatics to discover new, high efficiency perovskites for synthesis and testing in optoelectronic applications. This project expects to identify perovskite composition-property relationships to overcome current drawbacks of high performance perovskites (contain rare or toxic elements and low stability in oxidative and humid environments) by considered selection of elements and their properties. Expected outcomes from this project include new perovskites with commercial potential in critical areas such as energy conversion, photocatalysis and luminescence. This should provide significant benefits including approaches to materials discovery, novel materials and in renewable energy and environmental areas.Read moreRead less
Interfacial design for high performance carbon fibre polymer composites. This project aims to develop customisable surfaces on carbon fibres to complement any intended resin for composite materials. Poor fibre-to-matrix adhesion is currently a known weakness of carbon fibre composites, hindering the large scale translation of these materials into mass transport solutions The outcomes of this project will be the development of superior composites and the fundamental knowledge of what interfacial ....Interfacial design for high performance carbon fibre polymer composites. This project aims to develop customisable surfaces on carbon fibres to complement any intended resin for composite materials. Poor fibre-to-matrix adhesion is currently a known weakness of carbon fibre composites, hindering the large scale translation of these materials into mass transport solutions The outcomes of this project will be the development of superior composites and the fundamental knowledge of what interfacial molecular interactions are required to obtain composites able to tolerate high shear forces.Read moreRead less
A design-led approach for multifunctional composites . This project aims to remove some of the limitations of carbon fibre composites by introducing novel functionality into the underlying carbon fibre. The project expects to modify carbon fibres, predict their functionality and develop new high-performance resins. The expected outcomes include enabling carbon composite materials to have high strength-to-weight ratio, durability, toughness, minimal maintenance, without compromising processabilit ....A design-led approach for multifunctional composites . This project aims to remove some of the limitations of carbon fibre composites by introducing novel functionality into the underlying carbon fibre. The project expects to modify carbon fibres, predict their functionality and develop new high-performance resins. The expected outcomes include enabling carbon composite materials to have high strength-to-weight ratio, durability, toughness, minimal maintenance, without compromising processability and the ability to manufacture at high volumes. The benefits should include a significant boost to Australia’s ability to lead economically important manufacturing innovations across a range of sectors including defence, energy and construction. Read moreRead less
Surface ligation of nanomaterials for biomedical applications . The project aims to explore the synergistic effects co-ligands for target recognition and biofouling protection in nanoparticle surface patterns to enable practical atomic scale precision engineering of efficient and biofouling resistant nanosensors. The project will fundamentally characterise interfacial interactions and dynamics of ligated nano-surfaces and biomolecules via advanced computer modelling. Outcomes should include pra ....Surface ligation of nanomaterials for biomedical applications . The project aims to explore the synergistic effects co-ligands for target recognition and biofouling protection in nanoparticle surface patterns to enable practical atomic scale precision engineering of efficient and biofouling resistant nanosensors. The project will fundamentally characterise interfacial interactions and dynamics of ligated nano-surfaces and biomolecules via advanced computer modelling. Outcomes should include practical molecular design guidelines for functional ligands and predicted optimal patterns for combining functional and antifouling ligands on gold nanomaterials for biosensing technologies. The advanced predictive modelling capabilities will facilitate future practical engineering of efficient biomedical devices.Read moreRead less
Synthesising novel phases of carbon by shear-induced phase transformations. Carbon forms the hardest known solids and offers the opportunity for new materials with outstanding properties. The aim of this project is to establish a new technology for synthesising dense, diamond-like carbon materials without the need for high temperatures. The approach uses shear stress caused by non-hydrostatic compressions to drive phase changes in solids. Guided by modelling and using novel experimental techniqu ....Synthesising novel phases of carbon by shear-induced phase transformations. Carbon forms the hardest known solids and offers the opportunity for new materials with outstanding properties. The aim of this project is to establish a new technology for synthesising dense, diamond-like carbon materials without the need for high temperatures. The approach uses shear stress caused by non-hydrostatic compressions to drive phase changes in solids. Guided by modelling and using novel experimental techniques, this project seeks to understand and then exploit this remarkable phase change phenomenon. Expected outcomes include hard and tough coatings for high performance tools, impermeable encapsulations to enhance the longevity of bionic implants and a possible explanation for the mystery of deep earthquakes.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100128
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
High performance analytical tools to strengthen clean energy research. High performance analytical tools are vital to the success of emerging research fields of national priority. By filling a gap in materials routine characterisation capabilities, the equipment requested will lead to major advances in fundamental and applied research aimed at carbon abatement and clean energy technologies. This includes technologies for clean energy generation by solar means and from decarbonised fossil fuels, ....High performance analytical tools to strengthen clean energy research. High performance analytical tools are vital to the success of emerging research fields of national priority. By filling a gap in materials routine characterisation capabilities, the equipment requested will lead to major advances in fundamental and applied research aimed at carbon abatement and clean energy technologies. This includes technologies for clean energy generation by solar means and from decarbonised fossil fuels, efficient energy storage systems, advanced fuel cells for electricity generation, and hydrogen as the universal energy vector. Advancement of these technologies will bring solutions to the grand challenges facing Australia and in turn benefit industry and society.
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Aggregation control for high-performance polymer electronics. This project aims to exploit the behaviour of semiconducting polymer chains in solution to realise high-performance polymer electronics. This project will be achieved through a combination of simulation, theory, and X-ray measurements of solution-phase chain conformation and device studies. The project expects to create new predictive understanding of how the self organisation of semiconducting polymer chains determines thin-film micr ....Aggregation control for high-performance polymer electronics. This project aims to exploit the behaviour of semiconducting polymer chains in solution to realise high-performance polymer electronics. This project will be achieved through a combination of simulation, theory, and X-ray measurements of solution-phase chain conformation and device studies. The project expects to create new predictive understanding of how the self organisation of semiconducting polymer chains determines thin-film microstructure and thus charge transport in thin-film devices. Expected outcomes include new materials and processes for high-performance polymer transistors and enhanced interdisciplinary research partnerships. This approach should hasten the development of new technologies based on lightweight flexible electronic devices.Read moreRead less