Industrial Transformation Training Centres - Grant ID: IC130100011
Funder
Australian Research Council
Funding Amount
$2,695,000.00
Summary
Agents of change: transforming the food industry for Australia, Asia and beyond. Agents of change: transforming the food industry for Australia, Asia and beyond. This Training Centre will train a cohort of innovation scientists who will facilitate transformation of the Australian food industry. This will include manufacturing, processing and value chain analysis, and take advantage of opportunities for Australia to meet the demand for safe, healthy and high quality foods and retail-ready ingredi ....Agents of change: transforming the food industry for Australia, Asia and beyond. Agents of change: transforming the food industry for Australia, Asia and beyond. This Training Centre will train a cohort of innovation scientists who will facilitate transformation of the Australian food industry. This will include manufacturing, processing and value chain analysis, and take advantage of opportunities for Australia to meet the demand for safe, healthy and high quality foods and retail-ready ingredients in the Asian century.Read moreRead less
Yield improvement in large-scale bubble column fermenters. For companies operating in the global marketplace, yield differences of a few percent can be critically important. Improving yeast fermentation yield requires major advances in modelling the bubble size distribution and how this impacts micro- and macro-scale mixing. Model-based knowledge transfer via full-scale plant trials is a key outcome.
Ultrafine grained titanium for bio-implant applications. The project underpins the potential niche applications of ultrafine grained titanium for biomedical implants and establishes a knowledge base for expanding Australia's capacity for manufacturing titanium parts. The novel technology will lead to a broader usage of titanium by biomedical industry and promote the development of the titanium manufacturing industry in Australia. The development of ultrafine grained titanium specifically designe ....Ultrafine grained titanium for bio-implant applications. The project underpins the potential niche applications of ultrafine grained titanium for biomedical implants and establishes a knowledge base for expanding Australia's capacity for manufacturing titanium parts. The novel technology will lead to a broader usage of titanium by biomedical industry and promote the development of the titanium manufacturing industry in Australia. The development of ultrafine grained titanium specifically designed for bio-implants will increase Australia's competitiveness in the global market. The project targets at least three of the priority goals specified under National Research Priority breakthrough science, frontier technologies and advanced materials.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170101452
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Silk-based conformal pressure sensing devices. This project aims to develop silk biomaterials-based biocompatible and conformal pressure sensing devices and systems for sustainable wearable electronics. Biocompatible conformal sensing interfaces and sensor arrays will be developed for real-time highly sensitive measurement of pressure, critical for accurate and comprehensive health monitoring and electronic skins. It is believed that the wearable products will provide comfort, utility and accura ....Silk-based conformal pressure sensing devices. This project aims to develop silk biomaterials-based biocompatible and conformal pressure sensing devices and systems for sustainable wearable electronics. Biocompatible conformal sensing interfaces and sensor arrays will be developed for real-time highly sensitive measurement of pressure, critical for accurate and comprehensive health monitoring and electronic skins. It is believed that the wearable products will provide comfort, utility and accurate physical information to end users, and improve the performance of personnel working in demanding environments, such as in defence forces, athletics and outfield industrial operations, by continuously monitoring physiological parameters.Read moreRead less
New insights on the role of microalloying in high strength steels. By gaining fundamental understanding of microalloying element interactions at an atomic level during various stages of steel processing, this project aims to assist optimisation of steel compositions and address important industrial issues. Further modifications of the Castrip process of steel strip production will be examined.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100025
Funder
Australian Research Council
Funding Amount
$468,000.00
Summary
Electron microscopy facilities for in-situ materials characterisation. This project aims to significantly strengthen our national capability in high resolution in-situ transmission electron microscopy through the introduction of special in-situ specimen holders and an imaging detector. The project expects to advance knowledge critical for the design of advanced materials with outstanding properties. Expected outcomes of this project will provide critical support for thorough understanding of how ....Electron microscopy facilities for in-situ materials characterisation. This project aims to significantly strengthen our national capability in high resolution in-situ transmission electron microscopy through the introduction of special in-situ specimen holders and an imaging detector. The project expects to advance knowledge critical for the design of advanced materials with outstanding properties. Expected outcomes of this project will provide critical support for thorough understanding of how the microstructures of materials affect their mechanical, thermal, electrical, and magnetic properties and will facilitate strategic collaborations among Australian scientists. This should promote Australia’s global leadership in materials research and advanced manufacturing.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.
Autotransporter assembly: new insights and biotechnological potential. The objective of this project is to improve our understanding of a fundamental biological problem: how autotransporters are assembled into cellular membranes. Autotransporters are a large family of bacterial proteins that play key roles in the pathogenesis of several infectious diseases. Currently, the precise mechanism by which disease-causing molecules are assembled into the outer membranes of bacteria and mitochondria is p ....Autotransporter assembly: new insights and biotechnological potential. The objective of this project is to improve our understanding of a fundamental biological problem: how autotransporters are assembled into cellular membranes. Autotransporters are a large family of bacterial proteins that play key roles in the pathogenesis of several infectious diseases. Currently, the precise mechanism by which disease-causing molecules are assembled into the outer membranes of bacteria and mitochondria is poorly understood. The knowledge that the project develops may inform future strategies aimed at the rational treatment of bacterial and mitochondrial diseases.Read moreRead less
3D printing of titanium alloys for better than forged mechanical properties. This project represents a potential milestone in the development of three-dimensional printing of titanium alloys by selective laser melting. The purpose of this project is to develop essential fundamental knowledge and novel processing routes for three-dimensional printing of titanium alloys to ensure the achievement of better than forged mechanical properties for critical applications. The outcomes of the project are ....3D printing of titanium alloys for better than forged mechanical properties. This project represents a potential milestone in the development of three-dimensional printing of titanium alloys by selective laser melting. The purpose of this project is to develop essential fundamental knowledge and novel processing routes for three-dimensional printing of titanium alloys to ensure the achievement of better than forged mechanical properties for critical applications. The outcomes of the project are expected to enable access to new markets and supply chains, improve Australia's competitively advantage and national research strength in this critical sector of manufacturing, and enhance the long-term viability of Australia's resources and manufacturing industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100704
Funder
Australian Research Council
Funding Amount
$355,000.00
Summary
Development of Two-Dimensional MnO2 Nanosheets for a theranostic platform. This project aims to develop a novel diagnostic and therapeutic nanoplatform for cancer treatment that will improve cancer diagnosis and monitoring of treatment and reduce the side-effects of chemotherapy. The platform, based on biocompatible, ultrasmall and targeted two-dimensional manganese-oxide nanosheets, aims to combine simultaneous targeting, stimuli-responsive magnetic resonance imaging and drug release and delive ....Development of Two-Dimensional MnO2 Nanosheets for a theranostic platform. This project aims to develop a novel diagnostic and therapeutic nanoplatform for cancer treatment that will improve cancer diagnosis and monitoring of treatment and reduce the side-effects of chemotherapy. The platform, based on biocompatible, ultrasmall and targeted two-dimensional manganese-oxide nanosheets, aims to combine simultaneous targeting, stimuli-responsive magnetic resonance imaging and drug release and delivery. This should enable precise imaging of tumour tissues and enhanced drug delivery triggered by the physiological tumour microenvironment. The translation of this technology into clinical practice is likely to have significant benefits for the efficient treatment of cancer.Read moreRead less