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
Unravelling the structural origin of cyclic fatigue in ferroelectrics. Ferroelectric materials have extensive applications in electromechanical devices and memories and in service are often subjected to repeat mechanical and/or electrical loading, leading to cyclic fatigue and failure. This project aims to apply in-situ electron microscopy techniques and computational modelling to explore cyclic ferroelectric fatigue behaviour and to understand the relationships between local atomic scale struct ....Unravelling the structural origin of cyclic fatigue in ferroelectrics. Ferroelectric materials have extensive applications in electromechanical devices and memories and in service are often subjected to repeat mechanical and/or electrical loading, leading to cyclic fatigue and failure. This project aims to apply in-situ electron microscopy techniques and computational modelling to explore cyclic ferroelectric fatigue behaviour and to understand the relationships between local atomic scale structure and fatigue. The structural origin of ferroelectric fatigue has not been clear because of the limitations of previous measurement capabilities. This project will provide guidance in materials design to increase ferroelectric fatigue lifetime for more reliable ferroelectric-based electronic devices.Read moreRead less
Low-density high-performance proppants for hydraulic fracturing process . Australia has vast resources of unconventional oil/gas, which require hydraulic fracturing to stimulate production. This project aims to develop advanced low-density high-performance proppants from industry waste for hydraulic fracturing. This will be achieved by selecting purer SiO2 raw material, carefully designing the porous structure, and fully understanding its relationship with strength and pack conductivity. Low-den ....Low-density high-performance proppants for hydraulic fracturing process . Australia has vast resources of unconventional oil/gas, which require hydraulic fracturing to stimulate production. This project aims to develop advanced low-density high-performance proppants from industry waste for hydraulic fracturing. This will be achieved by selecting purer SiO2 raw material, carefully designing the porous structure, and fully understanding its relationship with strength and pack conductivity. Low-density means no chemicals in proppant transportation and application. Successful development of such high-performance proppants will significantly increase Australia oil/gas exploration and production with an environmental acceptable technology, a leap forward for the oil/gas industry in Australia and the world.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100773
Funder
Australian Research Council
Funding Amount
$354,446.00
Summary
Electric power and useful chemicals co-generation. This project aims to design and develop a fuel cell-reactor that can simultaneously produce electric power and value-added useful chemicals by utilising abundant and cheap gaseous fossil fuels such as natural gas and coal-seam gas. This project expects to realise zero greenhouse gas emissions during the use of fossil fuels to generate electricity, meanwhile opening up a new strategy in the development of highly efficient electro-catalysts for th ....Electric power and useful chemicals co-generation. This project aims to design and develop a fuel cell-reactor that can simultaneously produce electric power and value-added useful chemicals by utilising abundant and cheap gaseous fossil fuels such as natural gas and coal-seam gas. This project expects to realise zero greenhouse gas emissions during the use of fossil fuels to generate electricity, meanwhile opening up a new strategy in the development of highly efficient electro-catalysts for the advanced energy conversion and storage devices. The new technology developed in this project will lead to new breakthroughs in the commercial viability of fuel cell industries.Read moreRead less
AM of MAX Phase parts for applications in extreme environments. This project aims to develop techniques to synthesize MAX Phase compound materials in-situ using laser additive manufacturing. The project expects to increase jet engine fuel efficiency and thrust, and to fabricate longer-lasting parts for supersonic speed applications. The expected outcomes include well-developed additive manufacturing processes to make high performance engineering components with shape complexity for extreme envir ....AM of MAX Phase parts for applications in extreme environments. This project aims to develop techniques to synthesize MAX Phase compound materials in-situ using laser additive manufacturing. The project expects to increase jet engine fuel efficiency and thrust, and to fabricate longer-lasting parts for supersonic speed applications. The expected outcomes include well-developed additive manufacturing processes to make high performance engineering components with shape complexity for extreme environment applications, and new methods to increase the 3D printability of brittle materials. This should provide significant benefits to aerospace and defense industries through solving their long standing bottleneck material and processing problems. The outcomes also enhance Australia’s manufacturing capacity.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
Exploration of lead free ferroelectric crystals for transducer applications. This project aims to investigate lead free crystals, which are expected to possess high piezoelectric properties for medical imaging and underwater acoustics, as an alternative to toxic lead-based ferroelectrics which have been dominantly used in ultrasound transducers. The project will have significant impact on development of new lead-free ferroelectric crystals with desirable properties. This will benefit Australian ....Exploration of lead free ferroelectric crystals for transducer applications. This project aims to investigate lead free crystals, which are expected to possess high piezoelectric properties for medical imaging and underwater acoustics, as an alternative to toxic lead-based ferroelectrics which have been dominantly used in ultrasound transducers. The project will have significant impact on development of new lead-free ferroelectric crystals with desirable properties. This will benefit Australian industry by providing knowledge and technology of crystal growth, enabling advanced ultrasound transducers for medical imaging and underwater acoustic applications.Read moreRead less
Thermal transport by design for fast and efficient solar thermochemical fuel production. This project aims to demonstrate the utility of the thermal transport by design approach to develop functionally graded reactive materials that allow for fast and efficient solar thermo-chemical fuel production. Prediction capabilities will be developed to optimise multi-scale radiative and gas transport coupled with non-stoichiometric redox reactions. Synthesis gas production will be demonstrated using the ....Thermal transport by design for fast and efficient solar thermochemical fuel production. This project aims to demonstrate the utility of the thermal transport by design approach to develop functionally graded reactive materials that allow for fast and efficient solar thermo-chemical fuel production. Prediction capabilities will be developed to optimise multi-scale radiative and gas transport coupled with non-stoichiometric redox reactions. Synthesis gas production will be demonstrated using the new structures in a prototype solar thermochemical reactor under high-flux irradiation. This project aims to advance the fields of thermal sciences and high-temperature solar thermochemical processing and expand the engineering knowledge base to pave the way to sustainable transportation with the existing infrastructure.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
Beyond the Ferroelectric Field Effect Transistors. The von Neumann paradigm is the foundation of modern computing systems, which are based on the data exchange between central processing unit (CPU) and memory. The physical separation between the CPU and memory will cause von Neumann bottleneck – a memory wall to limit the data processing speed for contextually intelligent applications. This project aims to develop a novel ferroelectric field effect transistor that integrates a ferroelectric mat ....Beyond the Ferroelectric Field Effect Transistors. The von Neumann paradigm is the foundation of modern computing systems, which are based on the data exchange between central processing unit (CPU) and memory. The physical separation between the CPU and memory will cause von Neumann bottleneck – a memory wall to limit the data processing speed for contextually intelligent applications. This project aims to develop a novel ferroelectric field effect transistor that integrates a ferroelectric material into a semiconductor transistor structure to merge logic and memory functionalities in a single-device level. This will solve the memory wall problem while provide low power, high speed, high density and long data retention time for future logic-in-memory and data centric computing paradigms.Read moreRead less