Doped alumina with tailored material properties for battery applications. This project aims to develop tailored alumina materials for lithium ion battery separators through a novel in-situ approach that will: (1) produce uniform doped alumina for improved safety, (2) target specific surface and bulk material properties to increase the overall performance, and (3) reduce manufacturing costs by integrating the process with new technology developed for the production of high purity alumina. Signifi ....Doped alumina with tailored material properties for battery applications. This project aims to develop tailored alumina materials for lithium ion battery separators through a novel in-situ approach that will: (1) produce uniform doped alumina for improved safety, (2) target specific surface and bulk material properties to increase the overall performance, and (3) reduce manufacturing costs by integrating the process with new technology developed for the production of high purity alumina. Significant advances are proposed for overcoming current manufacturing limitations of doped alumina. Building research capacity and knowledge in battery material manufacturing will benefit a range of industries across Australia, whilst providing new opportunities for growth in local communities.Read moreRead less
Using 3D printing technology to develop architecturally-controlled synthetic bone substitutes. With the ageing population, there is increasing demand for synthetic materials that can regenerate bone. However, purely synthetic bone-substitute biomaterials cannot regenerate large bone defects in weight-bearing conditions due to their fragility. This project aims to develop a customisable, biodegradable, biocompatible and mechanically strong and tough scaffold that overcomes this long-standing prob ....Using 3D printing technology to develop architecturally-controlled synthetic bone substitutes. With the ageing population, there is increasing demand for synthetic materials that can regenerate bone. However, purely synthetic bone-substitute biomaterials cannot regenerate large bone defects in weight-bearing conditions due to their fragility. This project aims to develop a customisable, biodegradable, biocompatible and mechanically strong and tough scaffold that overcomes this long-standing problem. The project aims to achieve this by applying an innovative combination of cutting-edge 3D printing technology, advanced computational modelling and design techniques to produce a next-generation bioceramic scaffold with optimised architecture. This approach aims also to enable the possibility of producing custom-made implants for individual requirements.Read moreRead less
Stable perovskite-unlocking the full potential of low-cost solar cells. Despite impressive conversion efficiency, the perovskites' poor stability impedes their commercialization. This project aims to develop strategies for stable perovskite solar cells. This will be realized by a thorough understanding of the degradation origins with stimuli, and development of degradation mitigation strategies including materials and interfaces engineering, defect control and passivation, synergized by a system ....Stable perovskite-unlocking the full potential of low-cost solar cells. Despite impressive conversion efficiency, the perovskites' poor stability impedes their commercialization. This project aims to develop strategies for stable perovskite solar cells. This will be realized by a thorough understanding of the degradation origins with stimuli, and development of degradation mitigation strategies including materials and interfaces engineering, defect control and passivation, synergized by a systematic degradation evaluation, state-of-art multi-scale material and device characterizations and device modeling providing feedback for optimization. The project will bring new scientific findings, key technological step-change solutions, unlocking the full potential of perovskites for cheaper photovoltaic technologies.
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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
Advanced X-ray investigation of atomic and condensed matter science for Australian industry and scientific research. This project aims to improve the precision and calibration of measurements involving X-rays. This in turn will improve outcomes and instrumentation which utilise X-ray sources to probe structures and properties of advanced materials and biological samples.
Catalytic production of health food additives from crustacean wastes. Cost-effective production of new synthetic amino acids as value-added food additives from crustacean wastes is vital for waste recycling and a sustainable economy. This project will develop a unique catalytic system for the selective conversion of waste-derived compounds into tailor-made products. Advanced in situ spectroscopic techniques will be employed to establish the structure-reactivity relationship of working catalysts ....Catalytic production of health food additives from crustacean wastes. Cost-effective production of new synthetic amino acids as value-added food additives from crustacean wastes is vital for waste recycling and a sustainable economy. This project will develop a unique catalytic system for the selective conversion of waste-derived compounds 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 effciency and resource utilisation, which is essential for the success of the biorefining industry and a more environmentally-friendly chemical and food economy in Australia.Read moreRead less
Atomic-scale insights into interfaces in ultrafine-grained, low-solute alloys. This project will involve the development and application of innovative advanced microscopy methods for the study of the stability of new, ultrafine-grained alloys. This will allow the design of new alloys with exceptional properties for structural applications in environments that require ultra-high performance.
Thermoelectric devices for high-performing localised coolers. This project aims to develop a lightweight, low-energy-consumption, and high-durability wearable thermoelectric cooler for localised cooling using a novel industry-led approach, coupled with device design and materials engineering strategies. The key breakthrough expected is to design wearable thermoelectric coolers by using flexible substrates and thermoelectric materials with engineered chemistry and unique structures for achieving ....Thermoelectric devices for high-performing localised coolers. This project aims to develop a lightweight, low-energy-consumption, and high-durability wearable thermoelectric cooler for localised cooling using a novel industry-led approach, coupled with device design and materials engineering strategies. The key breakthrough expected is to design wearable thermoelectric coolers by using flexible substrates and thermoelectric materials with engineered chemistry and unique structures for achieving localised, instant, and controllable cooling with super low power input for personal usage in building and mining industry. Expected outcomes include innovative technologies for achieving high-efficiency cooling, which will provide significant economic and commercial benefits for Australia.Read moreRead less
Markers of milk quality in commercially produced UHT milks and milk powders. Efficient production of safe, wholesome food relies on the application of the best available knowledge of the food material and the processing technologies involved. This project applies proteomics, the most advanced protein analysis technique, to determine the changes that occur in milk during high heat treatment and subsequent storage of the heat-processed milk product. Armed with such knowledge, the dairy processin ....Markers of milk quality in commercially produced UHT milks and milk powders. Efficient production of safe, wholesome food relies on the application of the best available knowledge of the food material and the processing technologies involved. This project applies proteomics, the most advanced protein analysis technique, to determine the changes that occur in milk during high heat treatment and subsequent storage of the heat-processed milk product. Armed with such knowledge, the dairy processing industry will be able to make informed decisions about processing and storage conditions to ensure the final products provided to the consumer are of the highest possible quality. Read moreRead less
New high energy density cathode materials for lithium ion batteries. This project aims to develop new high-energy-density and low-cost lithium-rich cathode materials for advanced lithium-ion batteries that can store solar energy for Australian households and power the next generation electric vehicles. The project will design innovative strategies to suppress the voltage decay and capacity decline of the lithium rich materials over long-term cycling. The project expects to significantly improve ....New high energy density cathode materials for lithium ion batteries. This project aims to develop new high-energy-density and low-cost lithium-rich cathode materials for advanced lithium-ion batteries that can store solar energy for Australian households and power the next generation electric vehicles. The project will design innovative strategies to suppress the voltage decay and capacity decline of the lithium rich materials over long-term cycling. The project expects to significantly improve battery performance at a lower price and make a substantial impact to the energy supply technologies and industries in Australia and benefit the environment in the long run.Read moreRead less