Bubble Dynamics in Fine Droplets: Behaviour and Control. The principal vision in this project is to gain a deeper understanding of the formation, growth and collapse of bubbles within micron-size droplets and, in doing so, provide the technical underpinning necessary to advance the development of a range of emerging technologies in the light alloys manufacturing, atomisation, non-invasive medical therapy, drug delivery, and nucleation / solidification in thermal energy storage systems. Expected ....Bubble Dynamics in Fine Droplets: Behaviour and Control. The principal vision in this project is to gain a deeper understanding of the formation, growth and collapse of bubbles within micron-size droplets and, in doing so, provide the technical underpinning necessary to advance the development of a range of emerging technologies in the light alloys manufacturing, atomisation, non-invasive medical therapy, drug delivery, and nucleation / solidification in thermal energy storage systems. Expected outcomes include new experimental evidence and validated mathematical models for the analysis of bubbles encapsulated by fine droplets. The outcomes should significantly enhance Australia’s research and innovation capacity in the field of confined space bubble dynamics and related industrial applications. Read moreRead less
Modelling and characterisation of biomass materials for pneumatic transport. This project aims to develop a particle scale microprobe to capture the transient dynamics of biomass compaction, dilation and associated airflow for pneumatic conveying and potentially beyond. Low velocity, dense phase pneumatic transport presents the ideal method for transporting delicate biomass feedstocks. However, without the fundamental understanding of the compactive and dilative response of biomass ensembles, pn ....Modelling and characterisation of biomass materials for pneumatic transport. This project aims to develop a particle scale microprobe to capture the transient dynamics of biomass compaction, dilation and associated airflow for pneumatic conveying and potentially beyond. Low velocity, dense phase pneumatic transport presents the ideal method for transporting delicate biomass feedstocks. However, without the fundamental understanding of the compactive and dilative response of biomass ensembles, pneumatic conveyors will be over-designed and energy intensive. This project will enable accurate measurement of the motion, inertia and force information at the particle scale, to produce more accurate design protocols for dense phase biomass pneumatic transport.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101625
Funder
Australian Research Council
Funding Amount
$430,075.00
Summary
Developing an Advanced Drive-by Bridge Inspection Technology . 72% of bridges in Australia were constructed before 1976. Currently bridges are inspected by biennial visual inspection which is expensive, time consuming and subjective. Considering the large number of defective bridges in Australia and around the world and the limited budget of road authorities, this project aims to develop a low-cost and robust bridge monitoring framework by advanced data analytics, solely based on the response of ....Developing an Advanced Drive-by Bridge Inspection Technology . 72% of bridges in Australia were constructed before 1976. Currently bridges are inspected by biennial visual inspection which is expensive, time consuming and subjective. Considering the large number of defective bridges in Australia and around the world and the limited budget of road authorities, this project aims to develop a low-cost and robust bridge monitoring framework by advanced data analytics, solely based on the response of a moving vehicle passing over the bridge, with no equipment to be installed on the bridge. The project is significant because it opens a new direction for sustainable monitoring of such ageing infrastructure, consequently resulting in the lower costs of maintenance, enhanced safety and extended asset life.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH210100025
Funder
Australian Research Council
Funding Amount
$4,379,165.00
Summary
ARC Research Hub for Advanced Manufacturing with 2D Materials (AM2D). Australia holds large resources of critical 2D minerals – key enablers of several existing and emerging technologies in Energy Storage, Purification and Printed Electronics. The AM2D hub aims to provide a sophisticated environment for researchers and an industrial translation platform for manufacturers; a hub where leading academics, bright students, and industry partners come together to learn, apply, collaborate, innovate, a ....ARC Research Hub for Advanced Manufacturing with 2D Materials (AM2D). Australia holds large resources of critical 2D minerals – key enablers of several existing and emerging technologies in Energy Storage, Purification and Printed Electronics. The AM2D hub aims to provide a sophisticated environment for researchers and an industrial translation platform for manufacturers; a hub where leading academics, bright students, and industry partners come together to learn, apply, collaborate, innovate, and deliver industry transformation in advanced manufacturing. Anticipated outcomes include the transformation of newly discovered materials into globally traded, high-value 2D products, enabling Australian industries to capture more wealth and jobs from this large and growing market.
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Industrial Transformation Research Hubs - Grant ID: IH150100024
Funder
Australian Research Council
Funding Amount
$2,799,251.00
Summary
ARC Research Hub for Advanced Manufacturing of Medical Devices. ARC Research Hub for Advanced Manufacturing of Personalised Medical Devices. The project aims to transform Australia’s $10.8 billion medical technology sector by developing cost competitive technologies for the rapid production of personalised devices for Endovascular Aneurysm Repair (EVAR). To ensure the Australian industry remains globally competitive, this hub seeks to concurrently develop materials, technologies and flexible man ....ARC Research Hub for Advanced Manufacturing of Medical Devices. ARC Research Hub for Advanced Manufacturing of Personalised Medical Devices. The project aims to transform Australia’s $10.8 billion medical technology sector by developing cost competitive technologies for the rapid production of personalised devices for Endovascular Aneurysm Repair (EVAR). To ensure the Australian industry remains globally competitive, this hub seeks to concurrently develop materials, technologies and flexible manufacturing processes. The intended research outcomes include more efficient design and manufacturing processes and a new range of EVAR products generating increased market share and higher workforce capability. The resulting impacts should be better health outcomes, job creation and providing SMEs with new technologies and skills that can be transferred to the manufacture of products for other sectors.Read moreRead less
Functional-unit-based hierarchical nanocomposites for sustainable future. This project aims to address the limitation of current water electrolysis technologies through the development of functional-unit-based hierarchical nanocomposites for renewable energy generation with high efficiency. This project expects to generate new knowledge in next-generation catalyst design based on the deconvolution of energy loss in water electrolysis. The expected outcomes include the design and fabrication of n ....Functional-unit-based hierarchical nanocomposites for sustainable future. This project aims to address the limitation of current water electrolysis technologies through the development of functional-unit-based hierarchical nanocomposites for renewable energy generation with high efficiency. This project expects to generate new knowledge in next-generation catalyst design based on the deconvolution of energy loss in water electrolysis. The expected outcomes include the design and fabrication of novel catalysts with low overpotentials for green hydrogen production. This should provide significant benefits, such as low energy consumption and low carbon dioxide emissions in hydrogen production and advanced manufacturing, to the progress of renewable energy technology and the sustainable development of modern society.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101478
Funder
Australian Research Council
Funding Amount
$353,446.00
Summary
Long life sodium ion batteries by optimising initial coulombic efficiency. The project aims to develop novel structured phosphorus (Sn/P)-based composites as anode electrodes for sodium ion storage, which have high initial coulombic efficiency (charge capacity), high capacity and stable cycle life. Approaches of modifying surface structure will improve initial coulombic efficiency of Sn/P-based composites, and strategies to stabilise solid electrolyte interphase (SEI) film will obtain long-cycle ....Long life sodium ion batteries by optimising initial coulombic efficiency. The project aims to develop novel structured phosphorus (Sn/P)-based composites as anode electrodes for sodium ion storage, which have high initial coulombic efficiency (charge capacity), high capacity and stable cycle life. Approaches of modifying surface structure will improve initial coulombic efficiency of Sn/P-based composites, and strategies to stabilise solid electrolyte interphase (SEI) film will obtain long-cycle stability. The success of this project will greatly accelerate the commercialisation of sodium ion batteries and support the utilisation of renewable energy in Australia.Read moreRead less
Microwave photonics and photonic integration for advanced sensing. This project leverage breakthroughs in microwave photonics and integrated photonics for advanced sensing with wide range of applications in Internet of Things and healthcare. It develops compact and cost-effective micro-resonator sensors for unmanned aerial vehicle (UAV) applications in harsh environment, high-performance magnetic field sensor and high-density magnetic field sensing array with scalability. Outcomes herald disrupt ....Microwave photonics and photonic integration for advanced sensing. This project leverage breakthroughs in microwave photonics and integrated photonics for advanced sensing with wide range of applications in Internet of Things and healthcare. It develops compact and cost-effective micro-resonator sensors for unmanned aerial vehicle (UAV) applications in harsh environment, high-performance magnetic field sensor and high-density magnetic field sensing array with scalability. Outcomes herald disruptive, compact on-chip sensing techniques for reliable, high-resolution, low-noise and real-time sensing. Profound benefits include disaster management, environmental monitoring, industry growth, and major economic benefits underpinning a huge market encompassing UAV sensing and medical devices.Read moreRead less
High-voltage electrode materials for lithium-ion batteries. This project aims to establish a complete battery research system and develop high-voltage electrode materials for lithium-ion batteries through mechanistic understanding obtained in operando studies. Lithium-ion batteries are the most promising choice for portable electronic devices, including electric vehicles, due to their high power and energy performance compared with other battery technologies. The success of this project is expec ....High-voltage electrode materials for lithium-ion batteries. This project aims to establish a complete battery research system and develop high-voltage electrode materials for lithium-ion batteries through mechanistic understanding obtained in operando studies. Lithium-ion batteries are the most promising choice for portable electronic devices, including electric vehicles, due to their high power and energy performance compared with other battery technologies. The success of this project is expected to advance fundamental understanding of lithium-ion batteries, and provide techniques to develop a promising high-energy and high-power battery system.Read moreRead less