The systematic development of fundamentally important group 15 compounds: their applications to innovative industrial and environmental processes. The strong coordinating ability of organo-phosphorus/arsonic acids will be harnessed to support a series of metallic clusters that will be exploited for their use as magnetic materials in gas storage and as catalysts. The novel acids will be investigated for use as water soluble purification agents for, for example, mercury, uranium and lead.
Discovery Early Career Researcher Award - Grant ID: DE170100200
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Anion-templated functional architectures. This project aims to introduce a method for preparing large, complex materials from relatively simple precursors. Negatively-charged species, anions, will be used to assemble positively-charged organic molecules into three-dimensional structures, including cages and porous framework materials. This will increase fundamental understanding of how anions behave and their use in self-assembly processes. The structures made using this approach are expected to ....Anion-templated functional architectures. This project aims to introduce a method for preparing large, complex materials from relatively simple precursors. Negatively-charged species, anions, will be used to assemble positively-charged organic molecules into three-dimensional structures, including cages and porous framework materials. This will increase fundamental understanding of how anions behave and their use in self-assembly processes. The structures made using this approach are expected to remove dangerous environmental pollutants from water and store the industrially-relevant gases, hydrogen and carbon dioxide. This offers potential applications in clean energy technology (e.g. hydrogen storage for fuel cells) and environmental remediation (carbon dioxide storage, polycyclic aromatic hydrocarbon removal).Read moreRead less
Electronic functionality in nanoscale materials: from discovery to design. This project will develop innovative multifunctional carbon/boron-nitride nanomaterials by devising new strategies to manipulate their electronic functionality. Outcomes will include technological breakthroughs leading to smart materials for energy storage, greenhouse gas emission reduction and nanoelectronics.
Sodium borohydride for solid-state green hydrogen export. This project aims to develop a new method of producing, storing, and exporting green hydrogen using Australian resources. Sodium borohydride will be produced from borax using renewable energy and exported internationally to countries that desire hydrogen from renewable sources to replace fossil fuels. Green hydrogen will be released from sodium borohydride by adding water. The spent material will then be shipped back to Australia for recy ....Sodium borohydride for solid-state green hydrogen export. This project aims to develop a new method of producing, storing, and exporting green hydrogen using Australian resources. Sodium borohydride will be produced from borax using renewable energy and exported internationally to countries that desire hydrogen from renewable sources to replace fossil fuels. Green hydrogen will be released from sodium borohydride by adding water. The spent material will then be shipped back to Australia for recycling back to sodium borohydride, creating a closed-loop energy cycle using renewable energy. This will create a new export industry in Australia by expanding current mining expertise whilst harnessing our wealth of renewable energy to potentially deliver billions of dollars of revenue.Read moreRead less
Functional molecular nanomaterials. The design and construction of advanced nanomaterials is a key step in the push towards more efficient energy systems and smarter technologies. Through the strategic assembly of new classes of molecular nanomaterials, this project will lead to important fundamental advances in nanoscience and will underpin a range of new high-level technologies.
Discovery Early Career Researcher Award - Grant ID: DE180101030
Funder
Australian Research Council
Funding Amount
$368,446.00
Summary
Monoatomic metal doping of carbon-based nanomaterials for hydrogen storage. This project aims to present a new concept of monoatomic metal doped carbon-based nanomaterials as advanced solid-state hydrogen storage materials (S-HSMs) for hydrogen fuel cells. The key feature for this synthesis is the use of the unique “defect” structures in carbon lattice as the efficient anchoring sites to immobilise the metal species at atomic level. This project is expected to create new knowledge of atomic inte ....Monoatomic metal doping of carbon-based nanomaterials for hydrogen storage. This project aims to present a new concept of monoatomic metal doped carbon-based nanomaterials as advanced solid-state hydrogen storage materials (S-HSMs) for hydrogen fuel cells. The key feature for this synthesis is the use of the unique “defect” structures in carbon lattice as the efficient anchoring sites to immobilise the metal species at atomic level. This project is expected to create new knowledge of atomic interface catalysis and develop practical applications of S-HSMs in storage tanks for fuel cells, leading to reduction of carbon dioxide emissions and alleviation of air pollution. The success of this project will greatly enhance the Australian clean energy industries.Read moreRead less
Hybrid Toughening of Carbon Fibre Composites for Liquid Hydrogen Storage. This project aims to develop hybrid toughening technologies to overcome the major problem of transverse matrix cracking and splitting in existing carbon fibre composites when subjected to thermal-mechanical loading at the ultracold liquid hydrogen temperature. Nano-toughened thin-ply carbon fibre layers will be hybridised with standard-ply laminates to sustain internal pressure and external impact loading at cryogenic temp ....Hybrid Toughening of Carbon Fibre Composites for Liquid Hydrogen Storage. This project aims to develop hybrid toughening technologies to overcome the major problem of transverse matrix cracking and splitting in existing carbon fibre composites when subjected to thermal-mechanical loading at the ultracold liquid hydrogen temperature. Nano-toughened thin-ply carbon fibre layers will be hybridised with standard-ply laminates to sustain internal pressure and external impact loading at cryogenic temperatures without leaks. The hybrid composites are expected to enable Australian companies to engineer, manufacture and export lightweight carbon fibre tanks for storing and exporting liquid hydrogen, which is emerging as a transformational opportunity for Australia to become a global supplier of green energy.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100223
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Advanced X-ray diffraction facility for high energy and extreme conditions. X-ray powder diffraction is a powerful technique for determining the structure of matter at the atomic scale. This project will establish a new Australian capability for X-ray powder diffraction under extreme conditions that emulate real harsh service environments for advanced functional materials.
Industrial Transformation Training Centres - Grant ID: IC200100023
Funder
Australian Research Council
Funding Amount
$4,920,490.00
Summary
ARC Training Centre for The Global Hydrogen Economy. The centre aims to transform Australia into a hydrogen powerhouse by building enabling capacity in hydrogen innovation in a short timeframe. Australia is well-positioned to capitalise on the emerging global growth of hydrogen, however to be competitive and produce at scale, we need cost-effective hydrogen technologies and capabilities for transitioning hydrogen into industries. This innovative, five-year program will generate new technologies ....ARC Training Centre for The Global Hydrogen Economy. The centre aims to transform Australia into a hydrogen powerhouse by building enabling capacity in hydrogen innovation in a short timeframe. Australia is well-positioned to capitalise on the emerging global growth of hydrogen, however to be competitive and produce at scale, we need cost-effective hydrogen technologies and capabilities for transitioning hydrogen into industries. This innovative, five-year program will generate new technologies and equip a future workforce of industry-focused engineers with advanced skills for development and scaling-up of hydrogen generation and transport. Benefits include: export of hydrogen fuel and advanced technologies; job creation; and a lower emissions domestic energy industry.Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100215
Funder
Australian Research Council
Funding Amount
$440,926.00
Summary
Design and optimisation of metal hydride hydrogen storage tanks. This project aims to tackle the bottlenecks of the current metal hydride hydrogen storage tank developed by the key industry partner LAVO, i.e., limited storage capacity and non-efficient structure design. Through advanced numerical modelling and machine learning methods, the metal hydride hydrogen storage tank will be optimised by redesigning advanced heat management systems and optimised hydride materials, enabling it to store an ....Design and optimisation of metal hydride hydrogen storage tanks. This project aims to tackle the bottlenecks of the current metal hydride hydrogen storage tank developed by the key industry partner LAVO, i.e., limited storage capacity and non-efficient structure design. Through advanced numerical modelling and machine learning methods, the metal hydride hydrogen storage tank will be optimised by redesigning advanced heat management systems and optimised hydride materials, enabling it to store and deliver hydrogen in a more controllable way with high performance. Expected outcomes of the project include the numerical platform to improve the material and design iteration and a prototype of the next-generation metal hydride hydrogen storage system. This opens a new market for Australian-H2 storage tanks.
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