Mid-Career Industry Fellowships - Grant ID: IM230100125
Funder
Australian Research Council
Funding Amount
$1,053,296.00
Summary
Life prediction and optimisation of advanced first-wall fusion materials. The project focusses on accelerating the development radiation-tolerant materials for fusion energy, in collaboration with HB11 and Tokamak Energy. Specifically, we aim to understand the degradation mechanisms of the “first-wall” component, which is exposed to high energy radiation. In turn, this will (a) enable accurate life assessments of the component, and (b) inform how to optimise it material for longer-lasting fusion ....Life prediction and optimisation of advanced first-wall fusion materials. The project focusses on accelerating the development radiation-tolerant materials for fusion energy, in collaboration with HB11 and Tokamak Energy. Specifically, we aim to understand the degradation mechanisms of the “first-wall” component, which is exposed to high energy radiation. In turn, this will (a) enable accurate life assessments of the component, and (b) inform how to optimise it material for longer-lasting fusion devices. The outcomes directly reduce the cost of energy produced by the partner’s fusion devices, help bridge the gap from TRL 3 to 6, and provide valuable inputs for techno-economic models and licensing applications. The fellowship will also enhance Australia’s prominence in the international fusion energy stage.Read moreRead less
Advanced shield materials for compact fusion energy. We aim to predict how materials used for shielding sensitive components in nuclear fusion reactors will degrade over time. We will use this knowledge to design advanced alloys for radiation shield, which are critical for the development of more compact fusion reactors design, with lower construction cost, and shorter assembly time. These advanced shield materials may also be used in other applications in radiation fields (e.g. space, nuclear m ....Advanced shield materials for compact fusion energy. We aim to predict how materials used for shielding sensitive components in nuclear fusion reactors will degrade over time. We will use this knowledge to design advanced alloys for radiation shield, which are critical for the development of more compact fusion reactors design, with lower construction cost, and shorter assembly time. These advanced shield materials may also be used in other applications in radiation fields (e.g. space, nuclear medicine). The project also seeks to extend the Australian nuclear research capability by developing an innovative technique to study radiation damage using the OPAL reactor at ANSTO.Read moreRead less
Engineering nanomaterial interactions with the cell surface. This Fellowship aims to advance understanding of the endothelial cell surface, a key tissue barrier, and its interactions with nanomaterials. Enabled by cross-disciplinary collaboration, it expects to develop knowledge in matrix biology of the cell surface and materials as well as new methods to analyse their interactions. This is expected to unravel causal relationships between nanomaterial features and interactions at the cell surfac ....Engineering nanomaterial interactions with the cell surface. This Fellowship aims to advance understanding of the endothelial cell surface, a key tissue barrier, and its interactions with nanomaterials. Enabled by cross-disciplinary collaboration, it expects to develop knowledge in matrix biology of the cell surface and materials as well as new methods to analyse their interactions. This is expected to unravel causal relationships between nanomaterial features and interactions at the cell surface which will be integrated to engineer optimised materials. This will address the current and critical challenges of nanomaterial technologies in the efficient and targeted interactions with cells with long-term benefits for the consumer, biotechnology and healthcare sectors.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100130
Funder
Australian Research Council
Funding Amount
$1,300,000.00
Summary
Thermophysical Property Analysers for Materials under Extreme Environments. The development of new materials with properties specifically tailored to withstand the extreme environments begins with understanding the physical nature of the processes involved, including the properties of atoms and molecules extending from the nanoscale to the collective behaviour at the macroscale. This relies on the knowledge achieved with new capabilities of analytical tools to open new avenues for developing the ....Thermophysical Property Analysers for Materials under Extreme Environments. The development of new materials with properties specifically tailored to withstand the extreme environments begins with understanding the physical nature of the processes involved, including the properties of atoms and molecules extending from the nanoscale to the collective behaviour at the macroscale. This relies on the knowledge achieved with new capabilities of analytical tools to open new avenues for developing the materials. This project aims to strengthen Australian research activities in the development of advanced materials for energy, defence and space, and advanced manufacturing technologies through establishing a high temperature, high pressure and high force materials characterisation suite for extreme environments at UNSW.Read moreRead less
Integrated nonmetal-metal single-atom catalysis for selective synthesis. Single atom catalysts can achieve the maximum efficiency of active sites for a reaction. This project will develop integrated nonmetal and metal single atom-based catalysts for selective oxidation towards clean production and organic waste conversion to value-added polymers for carbon recycle. The project will result in new functional materials and green catalytic processes for chemical synthesis and waste reduction, and ad ....Integrated nonmetal-metal single-atom catalysis for selective synthesis. Single atom catalysts can achieve the maximum efficiency of active sites for a reaction. This project will develop integrated nonmetal and metal single atom-based catalysts for selective oxidation towards clean production and organic waste conversion to value-added polymers for carbon recycle. The project will result in new functional materials and green catalytic processes for chemical synthesis and waste reduction, and advance fundamental understanding of molecular structure of materials for catalyst design and process engineering for industrial applications. The outcomes will promote the development of chemical industry, waste recycle and green environment in Australia, making significant benefits to economics and society.Read moreRead less
Programming physical and biological cues to promote vessel growth . This project aims to engineer new hydrogel-based biomaterials that allow spatio-temporal modulation of physical and biological cues to direct blood vessels growth, as well as compatible with advanced bioprinting platforms. It will generate new knowledge in biomaterials, biofabrication and advanced material processing. Expected outcomes include new knowledge in biomaterial-vascular interaction, novel vascular bioinks, cross-disci ....Programming physical and biological cues to promote vessel growth . This project aims to engineer new hydrogel-based biomaterials that allow spatio-temporal modulation of physical and biological cues to direct blood vessels growth, as well as compatible with advanced bioprinting platforms. It will generate new knowledge in biomaterials, biofabrication and advanced material processing. Expected outcomes include new knowledge in biomaterial-vascular interaction, novel vascular bioinks, cross-disciplinary, international collaboration and research training. This project will provide significant benefit to Australia's scholarly output and reputation, as well as long term benefits to biomedical, veterinary and cosmetic through new materials and cutting-edge manufacturing platforms. Read moreRead less
Nano-engineering of hierarchical catalysts for renewable chemicals. Producing high-value chemicals based on renewable alternatives -biomass resources is vital for the climate and a sustainable economy. This project will develop a unique nano-engineering approach to design hierarchical catalysts for the selective conversion of biomass into tailor-made products. Advanced in situ spectroscopic techniques will be employed to establish the structure-reactivity relationship of working catalysts and th ....Nano-engineering of hierarchical catalysts for renewable chemicals. Producing high-value chemicals based on renewable alternatives -biomass resources is vital for the climate and a sustainable economy. This project will develop a unique nano-engineering approach to design hierarchical catalysts for the selective conversion of biomass into tailor-made products. Advanced in situ spectroscopic techniques will be employed to establish the structure-reactivity relationship of working catalysts and thereby manipulate the key factors governing the activity/selectivity. Such cutting-edge knowledge gained is crucial for optimising process efficiency and resource utilisation, which is essential for the success of the biorefining industry and a more environmentally-friendly chemical economy in Australia.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL230100100
Funder
Australian Research Council
Funding Amount
$3,300,000.00
Summary
Forces in Nature: Tissue mechanics and cell sociology. Epithelial cells cover surfaces in the body, forming a shield to protect us from the environment. Despite their importance, we understand poorly how the cells communicate. This project aims to test the novel concept that epithelial cells communicate via transmission and detection of mechanical forces, using an innovative combination of cellular and biophysical experiments and physical theory. The expected outcomes are new knowledge, interdis ....Forces in Nature: Tissue mechanics and cell sociology. Epithelial cells cover surfaces in the body, forming a shield to protect us from the environment. Despite their importance, we understand poorly how the cells communicate. This project aims to test the novel concept that epithelial cells communicate via transmission and detection of mechanical forces, using an innovative combination of cellular and biophysical experiments and physical theory. The expected outcomes are new knowledge, interdisciplinary training for young scientists, new national research capacity and growing international collaborations. Benefits include enhancing Australia’s scientific linkages and research capacity and providing fundamental knowledge that could lead to future advances in bioengineering and drug discovery. Read moreRead less
Identifying how cortical bone microstructure deteriorates with age. This project aims to define the disruptions responsible for the gradual weakening of the skeleton in ageing by integrating a range of high-resolution imaging, biomechanical, and computational methods. The expected significance of this project includes a full definition and comparison of the cellular and subcellular organisation of bone from young and elderly individuals. Expected outcomes of this international project include th ....Identifying how cortical bone microstructure deteriorates with age. This project aims to define the disruptions responsible for the gradual weakening of the skeleton in ageing by integrating a range of high-resolution imaging, biomechanical, and computational methods. The expected significance of this project includes a full definition and comparison of the cellular and subcellular organisation of bone from young and elderly individuals. Expected outcomes of this international project include the establishment of a new multidisciplinary research team, and the development of a new data-driven theoretical framework for understanding the nature and the causes of age-related bone fragility. Potential long-term benefits include new ways to treat age-related osteoporosis.Read moreRead less