Industrial Transformation Training Centres - Grant ID: IC170100023
Funder
Australian Research Council
Funding Amount
$4,619,950.00
Summary
ARC Training Centre for Cubesats, Uncrewed Aerial Vehicles, and Their Applications. The ARC Training Centre for CubeSats, Unmanned Aerial Vehicles and their Applications aims to train the next generation of workers in cutting edge advanced manufacturing, entrepreneurship, and commercial space and unmanned aerial vehicle applications. The Australian economy, security, and society increasingly rely on access to space for vital data and services, and a skilled workforce is required to grow the sec ....ARC Training Centre for Cubesats, Uncrewed Aerial Vehicles, and Their Applications. The ARC Training Centre for CubeSats, Unmanned Aerial Vehicles and their Applications aims to train the next generation of workers in cutting edge advanced manufacturing, entrepreneurship, and commercial space and unmanned aerial vehicle applications. The Australian economy, security, and society increasingly rely on access to space for vital data and services, and a skilled workforce is required to grow the sector and capitalise on global opportunities. Of great commercial value, with very low costs, CubeSats are a new class of small satellites, which with UAVs are disrupting the international satellite market. The expected outcome of this Training Centre is to develop new instruments, technology and products to solve crucial problems, and develop a world-class Australian industry in CubeSats, unmanned aerial vehicles, and related products.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102906
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Topology optimisation for advanced engineered nanostructures. Advanced technological innovation requires extraordinary material properties, which can be generated directly from engineered nanostructures by manipulating surface plasmon resonances. The project will develop a new computational method for nanostructural design and expect to benefit aerospace, biomedical, optical and energy engineering fields.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100194
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Optical diagnostics for the investigation of high-speed energetic processes. Optical diagnostics for the investigation of high-speed energetic processes:
The project seeks to establish equipment to enable the investigation of high-speed energetic processes. Such processes, where large amounts of energy are released over a short time frame, occur in nature and almost every field of science and engineering, and their investigation is a formidable challenge. This challenge is designed to be met th ....Optical diagnostics for the investigation of high-speed energetic processes. Optical diagnostics for the investigation of high-speed energetic processes:
The project seeks to establish equipment to enable the investigation of high-speed energetic processes. Such processes, where large amounts of energy are released over a short time frame, occur in nature and almost every field of science and engineering, and their investigation is a formidable challenge. This challenge is designed to be met through the combined use of state-of-the-art flow visualisation, thermography and spectrometry equipment. These diagnostics would open avenues into so far impossible or difficult to conduct research on highly transient phenomena in various research fields, which include various aspects of fluid mechanics, combustion, and fracture mechanics. The equipment would be instrumental in the design of better and innovative machines, materials, instruments and processes.Read moreRead less
Integrity prediction of ground precision surfaces. This project aims to establish a new approach to enable a reliable and accurate prediction of precision surface grinding. Precision grinding is often the final step in the manufacturing chains for a broad range of metal, ceramic, optical glass and semiconductor components, which must have ultra-high surface integrity and accurate dimensions. To date, the surface integrity of a ground component cannot be predicted due to the involvement of many r ....Integrity prediction of ground precision surfaces. This project aims to establish a new approach to enable a reliable and accurate prediction of precision surface grinding. Precision grinding is often the final step in the manufacturing chains for a broad range of metal, ceramic, optical glass and semiconductor components, which must have ultra-high surface integrity and accurate dimensions. To date, the surface integrity of a ground component cannot be predicted due to the involvement of many random factors and variables in a precision surface grinding process, resulting in high failure rates and processes requiring repeated surface measurements. The novel approach for surface integrity prediction developed by this project will make a vital step forward in advancing the discipline of precision surfacing, establish a new knowledge base and bring about significant technological impacts to the manufacturing industry.Read moreRead less
A Multi-Optrode Array for Closed-Loop Bionics. We will design, implement and characterise a disruptive multi-channel optrode array (MOA) to record and stimulate excitable living tissue. The MOA will be a combination of individual optical electrodes (optrodes) that either comprise a new class of liquid crystals, used to passively sense extracellular biopotentials, or microphotovoltaic cells that will be used for electrical stimulation of excitable tissue. By employing light for communication with ....A Multi-Optrode Array for Closed-Loop Bionics. We will design, implement and characterise a disruptive multi-channel optrode array (MOA) to record and stimulate excitable living tissue. The MOA will be a combination of individual optical electrodes (optrodes) that either comprise a new class of liquid crystals, used to passively sense extracellular biopotentials, or microphotovoltaic cells that will be used for electrical stimulation of excitable tissue. By employing light for communication with optrodes, this new approach alleviates many of the wiring, packaging and encapsulation issues associated with existing devices. Computational modelling and in vitro testing in cardiac tissue and retinal neurons will demonstrate the utility of the MOA to sense and control electrical activity.Read moreRead less
Design of an optrode for next generation brain-machine interfaces. The project plans to use a new class of liquid crystals – deformed helix ferroelectric (DHF) liquid crystal – to sense extracellular biopotentials. In response to an applied electrical field, it has been shown that DHF crystals can modulate a polarised light source with extraordinary sensitivity and linear response down to the microvolt range. Using this technology, the project plans to initially design and test a single optrode ....Design of an optrode for next generation brain-machine interfaces. The project plans to use a new class of liquid crystals – deformed helix ferroelectric (DHF) liquid crystal – to sense extracellular biopotentials. In response to an applied electrical field, it has been shown that DHF crystals can modulate a polarised light source with extraordinary sensitivity and linear response down to the microvolt range. Using this technology, the project plans to initially design and test a single optrode device on the bench, before in vitro testing and characterisation using two-photon microscopy. The final design would be a higher density sensor array using a fibre optic source and multiple optical couplers. This may support the development of new ways to implant sensing and diagnostic devices in the body.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100016
Funder
Australian Research Council
Funding Amount
$490,000.00
Summary
Multi-scale fabrication facility for complex three-dimensional surface generation from nano to macro dimensions. This facility will support advances in the manufacturing of free-form surfaces with submicron features. Its unique characteristics, such as the universal profiling ability and nanometre accuracy across large dimensions, will enable many science and engineering innovations which are presently impossible to be realised in Australia.
An integral approach enabling the defect-free manufacture of microlens arrays. Free-form microlens arrays are of central importance to the advancement of science and frontier technologies such as electronics, optics, telecommunication, biotechnology, medical surgery, energy generation, agriculture, resource exploration, environment protection and security. Using an integral approach coupling processing-microstructure-property modelling, multi-scale mechanics and damage-free mould development. Th ....An integral approach enabling the defect-free manufacture of microlens arrays. Free-form microlens arrays are of central importance to the advancement of science and frontier technologies such as electronics, optics, telecommunication, biotechnology, medical surgery, energy generation, agriculture, resource exploration, environment protection and security. Using an integral approach coupling processing-microstructure-property modelling, multi-scale mechanics and damage-free mould development. This research project will establish novel theories and technologies for the defect-free manufacture of microlens arrays. The research outcomes will lay the foundation for defect-free fabrication of a wide class of high-integrity systems.Read moreRead less
A New Nano Tip Fabrication Technique for Atomic Force Microscopy. This project aims to develop a new fabrication technique for high-aspect-ratio (long and sharp) tips for atomic force microscopy. The technique is expected to overcome the current fabrication limitation, that is fabricating one tip at a time which is unsuitable for batch fabrication. The proposed technique can be scaled up to mass produce nano tips. The technique is expected to create new commercial products and intellectual prope ....A New Nano Tip Fabrication Technique for Atomic Force Microscopy. This project aims to develop a new fabrication technique for high-aspect-ratio (long and sharp) tips for atomic force microscopy. The technique is expected to overcome the current fabrication limitation, that is fabricating one tip at a time which is unsuitable for batch fabrication. The proposed technique can be scaled up to mass produce nano tips. The technique is expected to create new commercial products and intellectual property. This innovation will lead to the emergence of breakthrough technologies in nanofabrication and nanomaterials synthesis. The benefits to Australia include new job opportunities and the development of local expertise in the field.Read moreRead less
Creating a non-invasive window into the mind. This project aims to create better tools to study the human mind. This project expects to generate new knowledge that can be used to non-invasively image neuronal activity. Expected outcomes include the development of unique new Magnetic Resonance Imaging (MRI) instruments to study neuronal activity in both highly controlled laboratory conditions and in humans, with the spatial and temporal resolution needed to study the neuronal circuitry that drive ....Creating a non-invasive window into the mind. This project aims to create better tools to study the human mind. This project expects to generate new knowledge that can be used to non-invasively image neuronal activity. Expected outcomes include the development of unique new Magnetic Resonance Imaging (MRI) instruments to study neuronal activity in both highly controlled laboratory conditions and in humans, with the spatial and temporal resolution needed to study the neuronal circuitry that drives low and high-level brain functions, i.e., creating a window into the mind. In the future, outcomes from this study could improve our understanding of mental disorders, advance computer brain interface technology, and inspire the next paradigm shift in artificial intelligence.Read moreRead less