Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100151
Funder
Australian Research Council
Funding Amount
$744,000.00
Summary
Multi-kilohertz laser for attosecond and ultrafast science. Griffith University's Australian Attosecond Science Facility was established 12 years ago to facilitate internationally leading research into strong-field laser science. The facility is unique in Australia as it has the capability to precisely manipulate highly-amplified and ultra-short light pulses to investigate the dynamics of matter. The scientific outputs from the facility have delivered important new scientific advances in strong ....Multi-kilohertz laser for attosecond and ultrafast science. Griffith University's Australian Attosecond Science Facility was established 12 years ago to facilitate internationally leading research into strong-field laser science. The facility is unique in Australia as it has the capability to precisely manipulate highly-amplified and ultra-short light pulses to investigate the dynamics of matter. The scientific outputs from the facility have delivered important new scientific advances in strong-field physics enabling the development of new technologies. This grant will be used to procure an upgraded laser system enabling an order of magnitude enhancement of the output light for the next-generation research and maintaining international competitiveness of Australian investigators in this field.Read moreRead less
Bright x-ray beams from laser-driven microplasmas. This project aims to develop a new generation of bright, laser-like x-ray sources for laboratory use. X-ray sources underpin key diagnostic techniques in materials science, advancing applications from structural engineering through to ore processing and energy storage. However, the limited brightness of present-day laboratory x-ray sources restricts the utility and range of these diagnostic techniques. This research intends to use intense lasers ....Bright x-ray beams from laser-driven microplasmas. This project aims to develop a new generation of bright, laser-like x-ray sources for laboratory use. X-ray sources underpin key diagnostic techniques in materials science, advancing applications from structural engineering through to ore processing and energy storage. However, the limited brightness of present-day laboratory x-ray sources restricts the utility and range of these diagnostic techniques. This research intends to use intense lasers to create microscopic plasmas and drive high harmonic generation. The high harmonic generation process is already used to create laser-like ultraviolet light. By optimising the characteristics of the plasma medium, the project aims to extend bright high harmonic generation to the x-ray regime.Read moreRead less
Atomic scale imaging with high coherence electrons and ions. This project aims to combine a cold atom electron-ion source with a commercial microscope column for atomic-scale imaging in biosciences and materials science. Nanoscale imaging with electron and ion microscopy are tools for investigating the world at the atomic scale, underpinning development in modern technologies from semiconductor devices to medical treatments. This project will use ideas from laser cooling of atoms and atom optics ....Atomic scale imaging with high coherence electrons and ions. This project aims to combine a cold atom electron-ion source with a commercial microscope column for atomic-scale imaging in biosciences and materials science. Nanoscale imaging with electron and ion microscopy are tools for investigating the world at the atomic scale, underpinning development in modern technologies from semiconductor devices to medical treatments. This project will use ideas from laser cooling of atoms and atom optics to achieve new imaging modalities for time-lapse imaging of fundamental processes at the nano-scale. It will allow increasingly small scale resolution of fundamental processes at the nano-scale.Read moreRead less
A Micro-Physiological System to Mimic Human Microbiome-Organ Interactions. This project aims to mimic gut microbiome-organ interactions by developing a microbial-gut coculture chip, which can reversibly interface with other organs-on-chips. This is achieved through the systematic integration of highly customisable biofabrication and microfluidic technologies. This project fills a critical technological gap in the availability of an animal-alternative system to investigate microbiome-host interac ....A Micro-Physiological System to Mimic Human Microbiome-Organ Interactions. This project aims to mimic gut microbiome-organ interactions by developing a microbial-gut coculture chip, which can reversibly interface with other organs-on-chips. This is achieved through the systematic integration of highly customisable biofabrication and microfluidic technologies. This project fills a critical technological gap in the availability of an animal-alternative system to investigate microbiome-host interactions, which will greatly complement existing meta-omics approaches. The deliverables include a proof-of-concept system validated for gut-liver axis as well as the creation of new knowledge and framework to assimilate design thinking and advanced manufacturing to elevate tissue engineering into physiology engineering. Read moreRead less
Active channel organic transistors. The objective of our project is to create the next generation of electronic transistors based upon organic semiconductors. Specifically, the project will create devices for use in applications such as low power lighting, chemical sensing and lasers.
Australian Laureate Fellowships - Grant ID: FL160100089
Funder
Australian Research Council
Funding Amount
$2,600,796.00
Summary
In situ electron microscopy toward new materials and applications. In situ electron microscopy toward new materials and applications. This project aims to develop materials for structural and green energy applications, using spatially-resolved, dynamic in situ transmission electron microscopy to research fundamental mechanical, electrical, thermal, optical, optoelectronic and photovoltaic properties of diverse nanostructures. These techniques measure nanomaterial (one-dimensional nanotubes and n ....In situ electron microscopy toward new materials and applications. In situ electron microscopy toward new materials and applications. This project aims to develop materials for structural and green energy applications, using spatially-resolved, dynamic in situ transmission electron microscopy to research fundamental mechanical, electrical, thermal, optical, optoelectronic and photovoltaic properties of diverse nanostructures. These techniques measure nanomaterial (one-dimensional nanotubes and nanowires and two-dimensional graphene-like nanosheets) response to external stimuli, including mechanical, electrical, optical and thermal stimuli. Anticipated outcomes are new ultralight and superstrong structural composites and ‘green-energy’ nanomaterials, such as solar cells, touch panels, batteries, supercapacitors, field-effect transistors, light sensors and displays.Read moreRead less
Nanoscale control of energy and matter for future energy-efficient technologies. Unprecedented control of energy and matter in nanoscale fabrication will be achieved using non-equilibrium self-organised plasma-solid systems. The outcomes will lead to energy-efficient, environment- and human-health-friendly production of nanomaterials for future energy, health, information, food, water, environmental and security technologies.
Indoor Photovoltaics Enabled by Wide-Bandgap Perovskite Quantum Dots. This project aims to develop a high-efficiency indoor photovoltaic (PV) technology to provide reliable low-cost power in the multi-billion dollar “Internet of Things” (IoT) market. There are currently no devices that meet the requirements for maximum operating efficiency under indoor illumination. We propose to solve this problem by fabricating PV cells using colloidal perovskite quantum dots that offer class-leading stability ....Indoor Photovoltaics Enabled by Wide-Bandgap Perovskite Quantum Dots. This project aims to develop a high-efficiency indoor photovoltaic (PV) technology to provide reliable low-cost power in the multi-billion dollar “Internet of Things” (IoT) market. There are currently no devices that meet the requirements for maximum operating efficiency under indoor illumination. We propose to solve this problem by fabricating PV cells using colloidal perovskite quantum dots that offer class-leading stability and band gap tunability across the required range, enabled by quantum confinement. The outcome is the development of integrated self-powered IoT devices potentially impacting Advanced Manufacturing growth in Energy, Cyber Security, Food and Agribusiness, as all of these will ultimately rely on networked smart devices.Read moreRead less
Non-precious fuel cell cathode catalysts from carbon-based nanohybrids: a computational to experimental quest. This joint computational-experimental project will address significant problems including high cost, limited availability and poor performance in traditional platinum-based fuel cell technology. The outcomes are expected to help address global energy problems through the development of inexpensive fuel cell catalysts based on carbon nanohybrids.
Industrial Transformation Training Centres - Grant ID: IC180100049
Funder
Australian Research Council
Funding Amount
$4,380,454.00
Summary
ARC Training Centre for Future Energy Storage Technologies. The ARC Training Centre for Future Energy Storage Technologies aims to equip the next generation of researchers and the energy technology workforce with the skills needed to drive innovation, exploration and investigation so we safeguard our workers and industries. The Centre aims to challenge existing thinking and expand Australia’s capacity in energy storage and production. The Centre expects to create new knowledge and intellectual p ....ARC Training Centre for Future Energy Storage Technologies. The ARC Training Centre for Future Energy Storage Technologies aims to equip the next generation of researchers and the energy technology workforce with the skills needed to drive innovation, exploration and investigation so we safeguard our workers and industries. The Centre aims to challenge existing thinking and expand Australia’s capacity in energy storage and production. The Centre expects to create new knowledge and intellectual property in advanced energy materials, batteries and battery-control systems for integration into end user industries. This Centre will facilitate small to medium-sized enterprises to take a global leadership role in advancing and producing new age storage technologies. By harnessing the expertise of researchers and industry partners the Centre aims to deliver benefit to our economy, the community and the environment.
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