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Engineering nanomembranes for Long-term Implanted Flexible Electronics. This project aims to investigate the key technologies of inorganic semiconductor nanomembranes for long-lived bio-integrated electronics. Taking advantage of the well-established silicon carbide (SiC) synthesis and fabrication technology, the project expects to elucidate a new understanding of the SiC-on-polymer platform, establishing a foundational guideline for the development of chemically inert and mechanically flexible ....Engineering nanomembranes for Long-term Implanted Flexible Electronics. This project aims to investigate the key technologies of inorganic semiconductor nanomembranes for long-lived bio-integrated electronics. Taking advantage of the well-established silicon carbide (SiC) synthesis and fabrication technology, the project expects to elucidate a new understanding of the SiC-on-polymer platform, establishing a foundational guideline for the development of chemically inert and mechanically flexible devices. These findings will offer innovative solutions for daunting challenges in bio-integrated electronics, leveraging their safety, reliability, and long-term performance. The project expects to offer Australia cutting edge technologies and an impact profile in the fast-growing flexible bio-electronics market.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100004
Funder
Australian Research Council
Funding Amount
$762,800.00
Summary
Ultrafast Infrared Spectroscopy Facility. The Ultrafast Infrared Spectroscopy Facility will provide a suite of techniques spanning the visible to mid-infrared spectral regions, on time scales corresponding to the emission of light, and energy conversion in low energy advanced functional materials. Research performed with this equipment will include photonic and thermal energy conversion; nanophotonics; quantum technologies and new infrared functional materials. This facility will enhance capacit ....Ultrafast Infrared Spectroscopy Facility. The Ultrafast Infrared Spectroscopy Facility will provide a suite of techniques spanning the visible to mid-infrared spectral regions, on time scales corresponding to the emission of light, and energy conversion in low energy advanced functional materials. Research performed with this equipment will include photonic and thermal energy conversion; nanophotonics; quantum technologies and new infrared functional materials. This facility will enhance capacity in probing new materials and devices in the near and mid-infrared regions, and will increase institutional and cross-disciplinary research collaboration.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100045
Funder
Australian Research Council
Funding Amount
$410,000.00
Summary
Cryogenic microwave characterization facility for quantum technologies. This project will establish a multi-user, fast-turn-around cryogenic characterization facility for microwave superconducting quantum technologies that are critical components for quantum computer, networks and sensor systems. This facility will lead to a significant improvement in research efficiency, allowing for rapid optimization of devices and components prior to integration into a larger quantum system. Expected outcome ....Cryogenic microwave characterization facility for quantum technologies. This project will establish a multi-user, fast-turn-around cryogenic characterization facility for microwave superconducting quantum technologies that are critical components for quantum computer, networks and sensor systems. This facility will lead to a significant improvement in research efficiency, allowing for rapid optimization of devices and components prior to integration into a larger quantum system. Expected outcomes include the creation of new intellectual property, enhanced engagement with industry, and will further boost Australia's efforts to build a commercially scalable quantum computer. Read moreRead less
ARC Centre of Excellence for Gravitational Wave Discovery. ARC Centre of Excellence for Gravitational Wave Discovery. The mission of our Centre is to use gravitational waves to investigate the fundamental nature of relativistic gravity, ultra-dense matter, and cosmology. This will generate critical discoveries that cement Australia's leadership role in the gravitational wave mega-science instruments of the 2030s and 2040s. By bringing together a world-class team with broad and complementary expe ....ARC Centre of Excellence for Gravitational Wave Discovery. ARC Centre of Excellence for Gravitational Wave Discovery. The mission of our Centre is to use gravitational waves to investigate the fundamental nature of relativistic gravity, ultra-dense matter, and cosmology. This will generate critical discoveries that cement Australia's leadership role in the gravitational wave mega-science instruments of the 2030s and 2040s. By bringing together a world-class team with broad and complementary expertise we will develop core technologies for future detectors, discover new sources of gravitational waves, probe fundamental physics, and lay the foundations for an Australian gravitational wave observatory. Our discoveries will inspire Australia's youth to pursue high tech careers and position our staff and students to become leaders in both industry and academia.Read moreRead less
Engineered topological nanostructures – a new frontier in materials design. The aim of engineering and utilising topological defects such as domain walls and and skyrmions in functional materials is currently receiving tremendous attention. Their significance lies in a plethora of fascinating phenomena for fundamental research and future technological applications in nanoelectronics. One frontier area of research is negative capacitance nanoelectronics using such materials, carrying the prospect ....Engineered topological nanostructures – a new frontier in materials design. The aim of engineering and utilising topological defects such as domain walls and and skyrmions in functional materials is currently receiving tremendous attention. Their significance lies in a plethora of fascinating phenomena for fundamental research and future technological applications in nanoelectronics. One frontier area of research is negative capacitance nanoelectronics using such materials, carrying the prospect of revolutionizing ultralow energy electronics, which will be developed here. The project's expected outcomes are new concepts for the synthesis and design of topological nanostructures for such applications. The utilization of these materials will benefit efficient controllable functionality for future nanoelectronics.Read moreRead less
Planet Formation at Solar System Scales with the James Webb Space Telescope. Planetary systems like our own form within vast disks of primordial gas and dust around newborn stars. This project will observe such disks spanning a range of ages with the James Webb Space Telescope to reveal the detailed in-situ physics of planet-forming disks themselves. We will deliver the sharpest-ever infrared images in astronomy, exploiting the only Australian-designed instrument on the spacecraft: the Aperture ....Planet Formation at Solar System Scales with the James Webb Space Telescope. Planetary systems like our own form within vast disks of primordial gas and dust around newborn stars. This project will observe such disks spanning a range of ages with the James Webb Space Telescope to reveal the detailed in-situ physics of planet-forming disks themselves. We will deliver the sharpest-ever infrared images in astronomy, exploiting the only Australian-designed instrument on the spacecraft: the Aperture Masking Interferometer. This yields new physics for actively growing protoplanets, carved rings and gaps in disks, and gravitationally sculpted patterns of leftover cometary debris. Confronting state-of-the-art models with these data will immediately yield profound insights into planetary system formation, including our own.Read moreRead less
Congestion control in complex networks with higher-order interactions. Traffic congestion significantly costs the Australian economy and environment. This project aims to develop ground-breaking network models of urban traffic systems to build a new congestion control framework. The purpose of network modelling is to capture the interdependence between different parts of traffic systems, which facilitates studying congestion cascade within the network. The project expects to generate next genera ....Congestion control in complex networks with higher-order interactions. Traffic congestion significantly costs the Australian economy and environment. This project aims to develop ground-breaking network models of urban traffic systems to build a new congestion control framework. The purpose of network modelling is to capture the interdependence between different parts of traffic systems, which facilitates studying congestion cascade within the network. The project expects to generate next generation of network models for more effective congestion control. Expected outcomes include novel congestion control technologies that adjust traffic signals in real-time to optimally utilise the available road space. This should provide significant economic and environmental benefits to Australians by easing traffic jams.Read moreRead less
On the Combustion of Green Hydrogen in Future Energy Systems. This project aims to address key fundamental issues that will facilitate the combustion of hydrogen-based fuels for power and mobility. This is achieved by applying advanced laser diagnostics and novel computational methods to turbulent flames of hydrogen fuel blends hence generating new physical knowledge and predictive models. These will provide engineers with essential tools to design and operate fuel-flexible energy systems that s ....On the Combustion of Green Hydrogen in Future Energy Systems. This project aims to address key fundamental issues that will facilitate the combustion of hydrogen-based fuels for power and mobility. This is achieved by applying advanced laser diagnostics and novel computational methods to turbulent flames of hydrogen fuel blends hence generating new physical knowledge and predictive models. These will provide engineers with essential tools to design and operate fuel-flexible energy systems that speed up the critical transition towards employing green hydrogen. Expected outcomes include novel experimental methods and databases, reliable software, and graduates capable of facilitating this transition and accelerating the global decarbonization process while positioning Australia as a hydrogen superpower.Read moreRead less
Designing a spectrometer to search for life on extrasolar planets. Finding indicators of life on extrasolar planets is one of the greatest science questions of our time. Astronomers have found rocky, earth-like exoplanets; now we need powerful spectrometers to search for biomarkers in their atmospheres, detecting the faint imprints from molecules associated with life in the colour spectrum of stars. This project will develop the instruments and technologies required to enable spectroscopy with m ....Designing a spectrometer to search for life on extrasolar planets. Finding indicators of life on extrasolar planets is one of the greatest science questions of our time. Astronomers have found rocky, earth-like exoplanets; now we need powerful spectrometers to search for biomarkers in their atmospheres, detecting the faint imprints from molecules associated with life in the colour spectrum of stars. This project will develop the instruments and technologies required to enable spectroscopy with massively multiplexed telescopes. A spectrometer design with large spectral bandwidth and high resolution, optimised for a facility consisting of thousands of small telescopes, and novel optical fibres to link them, will open the door for breakthrough science requiring an entirely new class of telescope.Read moreRead less
Biophysics of the brain’s waste disposal system: Understanding why we sleep. This project aims to develop a new biophysical model of the brain, founded on the recently discovered glymphatic system responsible for waste disposal during sleep. It sets out to formulate, analyse, and validate rigorous new multiscale quantitative modelling – to advance the study of sleep and brain clearance dynamics, at timescales from hours to decades. Among expected outcomes are powerful models ready for applicatio ....Biophysics of the brain’s waste disposal system: Understanding why we sleep. This project aims to develop a new biophysical model of the brain, founded on the recently discovered glymphatic system responsible for waste disposal during sleep. It sets out to formulate, analyse, and validate rigorous new multiscale quantitative modelling – to advance the study of sleep and brain clearance dynamics, at timescales from hours to decades. Among expected outcomes are powerful models ready for application at both population and individual level, and testable predictions concerning the sleep patterns that lead to aggregation of waste in the brain and eventual cognitive decline. Project outcomes should also benefit society and the economy though translation into interventions for sleep disturbance – in future applied research.Read moreRead less