Micro-electromechanical technology for harnessing terahertz waves. This project proposes novel low-cost miniature devices for spectral, spatial and temporal manipulation of terahertz waves realised using a unified platform based on a single material and fabrication technology sufficiently generic to span the entire very broad terahertz band. It inherently overcomes the most hindering issue of current terahertz instruments relating to the limited span of the spectrum each tool can cover and the h ....Micro-electromechanical technology for harnessing terahertz waves. This project proposes novel low-cost miniature devices for spectral, spatial and temporal manipulation of terahertz waves realised using a unified platform based on a single material and fabrication technology sufficiently generic to span the entire very broad terahertz band. It inherently overcomes the most hindering issue of current terahertz instruments relating to the limited span of the spectrum each tool can cover and the high costs associated with increasing this span; removing the need for making spectral band compromises in the design of future tools. The intended outcome is a platform for terahertz spectroscopic imaging, target recognition, detection of chemical composition of objects, and future high-bandwidth communications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100471
Funder
Australian Research Council
Funding Amount
$456,318.00
Summary
Designing advanced Zn-ion batteries towards practical applications. Aqueous Zn-ion batteries (ZIBs) are much safer and cheaper than current Li-ion batteries due to the water-based electrolyte and abundant Zn reserves. However, the state-of-the-art ZIB technique faces huge challenges for practical applications due to the low cathode capacity and poor Zn anode reversibility. This project aims to design novel cathodes with a new-type mechanism and highly reversible Zn anodes. Accordingly, on-demand ....Designing advanced Zn-ion batteries towards practical applications. Aqueous Zn-ion batteries (ZIBs) are much safer and cheaper than current Li-ion batteries due to the water-based electrolyte and abundant Zn reserves. However, the state-of-the-art ZIB technique faces huge challenges for practical applications due to the low cathode capacity and poor Zn anode reversibility. This project aims to design novel cathodes with a new-type mechanism and highly reversible Zn anodes. Accordingly, on-demand large-size ZIBs and flexible devices under industrial parameters will also be developed. The success of this project will place Australia at the forefront of implementing safe and low-cost batteries in largescale smart grid systems, household markets, and wearable medical devices.Read moreRead less
Next-generation computational models to understand human joints . This project aims to investigate human joint systems through combining state-of-the-art imaging and high-fidelity biomechanical models. The methods developed in this project are expected to generate new ways of studying the dynamic response of musculoskeletal tissues to activity, including how musculoskeletal physiology can adapt to biomechanical stimuli. Expected outcomes include establishing a non-invasive method for characteris ....Next-generation computational models to understand human joints . This project aims to investigate human joint systems through combining state-of-the-art imaging and high-fidelity biomechanical models. The methods developed in this project are expected to generate new ways of studying the dynamic response of musculoskeletal tissues to activity, including how musculoskeletal physiology can adapt to biomechanical stimuli. Expected outcomes include establishing a non-invasive method for characterising whole joint systems. This project will provide significant knowledge gain on the biomechanical regulation of human joints across form, function, dynamics and loading which may help across many facets of society to guide physical activity choices.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL230100100
Funder
Australian Research Council
Funding Amount
$3,300,000.00
Summary
Forces in Nature: Tissue mechanics and cell sociology. Epithelial cells cover surfaces in the body, forming a shield to protect us from the environment. Despite their importance, we understand poorly how the cells communicate. This project aims to test the novel concept that epithelial cells communicate via transmission and detection of mechanical forces, using an innovative combination of cellular and biophysical experiments and physical theory. The expected outcomes are new knowledge, interdis ....Forces in Nature: Tissue mechanics and cell sociology. Epithelial cells cover surfaces in the body, forming a shield to protect us from the environment. Despite their importance, we understand poorly how the cells communicate. This project aims to test the novel concept that epithelial cells communicate via transmission and detection of mechanical forces, using an innovative combination of cellular and biophysical experiments and physical theory. The expected outcomes are new knowledge, interdisciplinary training for young scientists, new national research capacity and growing international collaborations. Benefits include enhancing Australia’s scientific linkages and research capacity and providing fundamental knowledge that could lead to future advances in bioengineering and drug discovery. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100338
Funder
Australian Research Council
Funding Amount
$448,721.00
Summary
Enabling solid state metal recycling with new numerical techniques. This project performs modelling to help develop an additive metal manufacturing process that makes use of scrap as input feed. It will develop new understanding of the key physical aspects of friction stir additive manufacturing and build a new efficient yet accurate continuum thermo-mechanical model for its simulation. This technology will enable metal deposition at rates an order of magnitude greater than conventional powder a ....Enabling solid state metal recycling with new numerical techniques. This project performs modelling to help develop an additive metal manufacturing process that makes use of scrap as input feed. It will develop new understanding of the key physical aspects of friction stir additive manufacturing and build a new efficient yet accurate continuum thermo-mechanical model for its simulation. This technology will enable metal deposition at rates an order of magnitude greater than conventional powder additive manufacturing methods. The new computational approach will be used to create processing and design maps. The work will facilitate greater use of high metal scrap and pave the way for more robust supply chains and new business models with application in automotive, mining, aerospace and military sectors.Read moreRead less
A Green Technology for Enhancing Resource Recovery from Sewage Sludge. This project aims to develop an innovative technology to recover valuable resource from sewage sludge by enhancing transformation of sewage sludge into high-value medium chain fatty acids and methane. Wastewater treatment generates large amounts of resource-rich sewage sludge. However, the poor biodegradability of sewage sludge is a key barrier that impedes the efficient resource recovery. By advancing the underpinning scienc ....A Green Technology for Enhancing Resource Recovery from Sewage Sludge. This project aims to develop an innovative technology to recover valuable resource from sewage sludge by enhancing transformation of sewage sludge into high-value medium chain fatty acids and methane. Wastewater treatment generates large amounts of resource-rich sewage sludge. However, the poor biodegradability of sewage sludge is a key barrier that impedes the efficient resource recovery. By advancing the underpinning science and introducing a novel technology that innovatively harnesses a human waste, the project expects to remove the barrier. Expected project outcomes will turn sewage sludge from an undesirable waste to a valuable resource. This should provide significant benefits for Australia’s renewable energy and resource sectors.Read moreRead less
Innovative Stable Free Radical-Substituted Conjugated Electronic Polymers. The project aims to develop an innovative class of stable free radicals side-chain substituted conjugated donor-acceptor electronic polymers with unique polaronic and radical charge transport capabilities. The targeted optoelectronic material class is unique and has not been explored in depth before. The combination of unpaired electrons and delocalized backbone -electrons delivers exciting modes of charge transfer that ....Innovative Stable Free Radical-Substituted Conjugated Electronic Polymers. The project aims to develop an innovative class of stable free radicals side-chain substituted conjugated donor-acceptor electronic polymers with unique polaronic and radical charge transport capabilities. The targeted optoelectronic material class is unique and has not been explored in depth before. The combination of unpaired electrons and delocalized backbone -electrons delivers exciting modes of charge transfer that provide these novel materials with clear potential as electroactive materials with applications in various nanoelectronics devices. Developing a fundamental understanding of charge transport properties and potential device applications will open up a new field of research in advanced optoelectronic technology. Read moreRead less
2D Multiferroics: From Materials Design to Device Conceptualization. This project aims to design new transistors with high efficiency and low energy costing for the storage applications based on two-dimensional multifunctional heterostructures. Extensive computational simulations and joint experiments will be employed to develop fundamental knowledge essential to understanding the phenomena of magnetoelectric coupling, which is used to guide rational device design and implementation. The designe ....2D Multiferroics: From Materials Design to Device Conceptualization. This project aims to design new transistors with high efficiency and low energy costing for the storage applications based on two-dimensional multifunctional heterostructures. Extensive computational simulations and joint experiments will be employed to develop fundamental knowledge essential to understanding the phenomena of magnetoelectric coupling, which is used to guide rational device design and implementation. The designed magnetoelectric heterostructures and the multiferroic devices are expected to provide strong foundations for technological innovations resulting in devices with superior functionality and efficiency. The outcome of the project will significantly benefit high-tech electronics.Read moreRead less
Novel test and design methods for base course reinforced flexible pavements. This project aims to develop the mechanics of geosynthetic-reinforced flexible pavements as an urgent need for the Australian pavement industry to build more sustainable and economical roads. Novel laboratory test apparatus and in-situ test programs, and mathematical models will be developed, for the first time, to capture the responses of reinforced base courses in a complete and optimised way to determine the paramete ....Novel test and design methods for base course reinforced flexible pavements. This project aims to develop the mechanics of geosynthetic-reinforced flexible pavements as an urgent need for the Australian pavement industry to build more sustainable and economical roads. Novel laboratory test apparatus and in-situ test programs, and mathematical models will be developed, for the first time, to capture the responses of reinforced base courses in a complete and optimised way to determine the parameters for pavement design and performance evaluation. The outcomes will enable reliable prediction of reinforced pavement behaviour, leading to better-performing geosynthetic products and more resilient pavements, reduced material usage and damage in pavements, and less environmental impact and maintenance cost.Read moreRead less
Understanding bone structure evolution using machine learning. Bone remodeling is the ancient process of bone resorption and formation that optimises material properties and has led to evolution of terrestrial vertebrates. To date it is not understood how remodeling achieves tuning of bone material. This proposal aims to develop a machine learning based approach, linking computational modeling and imaging to address this problem. Intended outcomes are development of a multiscale model of remodel ....Understanding bone structure evolution using machine learning. Bone remodeling is the ancient process of bone resorption and formation that optimises material properties and has led to evolution of terrestrial vertebrates. To date it is not understood how remodeling achieves tuning of bone material. This proposal aims to develop a machine learning based approach, linking computational modeling and imaging to address this problem. Intended outcomes are development of a multiscale model of remodeling and machine learning algorithms for image analysis. This approach will help establish a structural-functional link between remodeling and bone material optimisation which ultimately provides significant benefits for bone tissue engineering, fracture healing and improved therapies for osteoporosis. Read moreRead less