Australian Laureate Fellowships - Grant ID: FL190100014
Funder
Australian Research Council
Funding Amount
$2,871,982.00
Summary
New Technologies for Delivering Sustainable Free-form Architecture. This project aims to harness the full potential of digital technologies to significantly enhance the performance and reduce the environmental impact of free-form architecture of the future. The research expects to establish a fundamentally new computational platform capable of producing diverse and competitive designs, and an environmentally friendly manufacturing process for realising such designs. Expected outcomes include an ....New Technologies for Delivering Sustainable Free-form Architecture. This project aims to harness the full potential of digital technologies to significantly enhance the performance and reduce the environmental impact of free-form architecture of the future. The research expects to establish a fundamentally new computational platform capable of producing diverse and competitive designs, and an environmentally friendly manufacturing process for realising such designs. Expected outcomes include an unprecedented cloud-based interactive design tool, and a novel minimum-waste manufacturing technology for fabricating mass-customised building components. This project will transform the architecture, engineering and construction (AEC) sector and make the Australian manufacturing industry more competitive globally.Read moreRead less
Ultrasound-assisted fabrication of biofunctional materials. The project aims to develop a fundamental understanding of the mechanism involved in the synthetic process in order to control the physical and functional properties of core-shell biomaterials. Biofunctional core-shell materials are of scientific interest due to their potential use in a variety of applications including food manufacturing. Among existing methodologies for the synthesis of core-shell biomaterials, ultrasonic technology o ....Ultrasound-assisted fabrication of biofunctional materials. The project aims to develop a fundamental understanding of the mechanism involved in the synthetic process in order to control the physical and functional properties of core-shell biomaterials. Biofunctional core-shell materials are of scientific interest due to their potential use in a variety of applications including food manufacturing. Among existing methodologies for the synthesis of core-shell biomaterials, ultrasonic technology offers versatility and a wider choice of core and shell materials possessing specific biofunctionality. The outcomes of this project may include the establishment of a versatile technology for the fabrication of tailor-made biofunctional materials suitable for specific applications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100274
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Design of alloys over multiple grain scales for improving fatigue performance. The project will significantly improve the development of engineering alloy design with high fatigue resistance and produce important benefits to Australian manufacturing industries. It will also establish new knowledge and capability in modelling fatigue behaviours, thus producing great benefits to many science and engineering fields.
Interface structures mediating load transfer between soft and hard tissues. This project aims to develop a novel technology platform to mediate load transfer between synthetic and biological materials with dissimilar mechanical properties, creating an effective interface mechanism. It will generate new knowledge in materials engineering by combining interdisciplinary expertise and state-of-the-art technologies in computational modelling, biomaterials, and additive manufacturing. Expected outcome ....Interface structures mediating load transfer between soft and hard tissues. This project aims to develop a novel technology platform to mediate load transfer between synthetic and biological materials with dissimilar mechanical properties, creating an effective interface mechanism. It will generate new knowledge in materials engineering by combining interdisciplinary expertise and state-of-the-art technologies in computational modelling, biomaterials, and additive manufacturing. Expected outcomes are high-tech ceramic structures optimized to interface effectively between synthetic soft tissues and natural hard tissues. This could ultimately benefit Australian industry engaged in developing next-generation synthetic orthopaedic solutions, providing a significant competitive advantage in an expanding global market.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100219
Funder
Australian Research Council
Funding Amount
$343,551.00
Summary
Molecular mechanism for the regulation of Polycomb repressive complex 2. This project aims to determine how the histone methyltransferase Polycomb repressive complex 2 (PRC2) is regulated. The project expects to generate new knowledge in transcription regulation and epigenetics. The intended outcome is to enhance the national capabilities in two important fields, Polycomb biology and cryo-electron microscopy (cryo-EM). This should provide significant benefits, including strengthening of the epig ....Molecular mechanism for the regulation of Polycomb repressive complex 2. This project aims to determine how the histone methyltransferase Polycomb repressive complex 2 (PRC2) is regulated. The project expects to generate new knowledge in transcription regulation and epigenetics. The intended outcome is to enhance the national capabilities in two important fields, Polycomb biology and cryo-electron microscopy (cryo-EM). This should provide significant benefits, including strengthening of the epigenetic community through the development of innovative research program in Polycomb biology and the establishment of a national world-class cryo-EM community.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101669
Funder
Australian Research Council
Funding Amount
$430,485.00
Summary
Polycomb Group Proteins - Shaping Chromatin Architecture to Silence Genes . This project aims to address the fundamental question of how genes are switched off by studying a group of molecular off-switches, the polycomb group proteins. The project is expected to generate new knowledge in the area of gene regulation and epigenetics by combining innovative methods of structural biology and cell biology in an interdisciplinary way. The expected outcomes include a more complete picture of the molecu ....Polycomb Group Proteins - Shaping Chromatin Architecture to Silence Genes . This project aims to address the fundamental question of how genes are switched off by studying a group of molecular off-switches, the polycomb group proteins. The project is expected to generate new knowledge in the area of gene regulation and epigenetics by combining innovative methods of structural biology and cell biology in an interdisciplinary way. The expected outcomes include a more complete picture of the molecular mechanisms that regulate gene expression and the development of novel methods to image the genome. This should provide significant benefits, such as facilitated development of gene editing tools and regulatory circuits for synthetic biology, as well as novel capabilities to image the genome at high resolution Read moreRead less
Design of Non-Equilibrium Architectures: Leveraging High Entropy Materials. Novel metallic alloys, termed as ‘high entropy materials’, will be investigated as surface coatings in order to provide improved strength, corrosion and wear performance under extreme industrial environments. This new evolution in materials engineering is created by mixing at least 5 elements in equal ratios and has recently been proven to provide excellent functionality in the bulk form. The novelty of this project is t ....Design of Non-Equilibrium Architectures: Leveraging High Entropy Materials. Novel metallic alloys, termed as ‘high entropy materials’, will be investigated as surface coatings in order to provide improved strength, corrosion and wear performance under extreme industrial environments. This new evolution in materials engineering is created by mixing at least 5 elements in equal ratios and has recently been proven to provide excellent functionality in the bulk form. The novelty of this project is that thermal spray engineering will be employed to manufacture bespoke coatings for industries such as the mining and power generation sectors. We now need to understand the materials science for a technological tipping point that directly impacts manufacturing industries for improved performance, efficiency and reliability.Read moreRead less
Innovative aluminium extrusion: increased productivity through simulation. This project seeks to develop new approaches to increase the productivity and competitiveness of the Australian aluminium extrusion industry. The project will use customised simulation software to optimise the design of extrusion dies, thereby substantially reducing the time and cost of developing new extrusion dies. It intends to similarly optimise the processing conditions for high quality extrusion, further contributin ....Innovative aluminium extrusion: increased productivity through simulation. This project seeks to develop new approaches to increase the productivity and competitiveness of the Australian aluminium extrusion industry. The project will use customised simulation software to optimise the design of extrusion dies, thereby substantially reducing the time and cost of developing new extrusion dies. It intends to similarly optimise the processing conditions for high quality extrusion, further contributing to cost reduction. Anticipated project outcomes include fundamental models of material deformation behaviour and damage accumulation that, through computer simulation, will increase die life and reduce scrap.Read moreRead less
The molecular blue-print for a mitochondrial nanomachine. The objective of the project is to develop a comprehensive understanding of the architecture of a biological nanomachine through broad-reaching investigation of the molecular contacts that enable the component parts to work together. The project plans to take the foundation knowledge of each of the component parts and build a conceptual framework of engineering principles to understand how the nanomachine is assembled, using a breakthroug ....The molecular blue-print for a mitochondrial nanomachine. The objective of the project is to develop a comprehensive understanding of the architecture of a biological nanomachine through broad-reaching investigation of the molecular contacts that enable the component parts to work together. The project plans to take the foundation knowledge of each of the component parts and build a conceptual framework of engineering principles to understand how the nanomachine is assembled, using a breakthrough technology to address the precise architecture of the component parts within the nanomachine.Read moreRead less
Micro-roll forming of metal bipolar plates for fuel cells. This project aims to develop a novel forming technology for the production of metal bipolar plates for fuel cells: micro-roll forming. This poses a number of challenges particularly due to the low material thickness to be formed. These challenges include the development of advanced models that account for size effects in the process and represent the unique deformation conditions and material fracture behaviour. The project plans to prod ....Micro-roll forming of metal bipolar plates for fuel cells. This project aims to develop a novel forming technology for the production of metal bipolar plates for fuel cells: micro-roll forming. This poses a number of challenges particularly due to the low material thickness to be formed. These challenges include the development of advanced models that account for size effects in the process and represent the unique deformation conditions and material fracture behaviour. The project plans to produce prototypes and to compare part complexity with that achievable by conventional micro stamping. The intended outcome of the project includes advanced computer models for process design and the new micro-forming technology validated through extensive laboratory and plant trials.Read moreRead less