A high speed, high fidelity 3D printer for fabricating microfluidic devices. This project aims to develop a novel 3D printer offering the highest resolution available and fastest printing speed for the single-step manufacturing of complex microfluidic devices. New resins developed to exploit the inert liquid interface layer printing approach will provide unprecedented capability to create micron sized channels interconnected in 3D space and fabricate Lab-on-a-Chip systems that cannot be generate ....A high speed, high fidelity 3D printer for fabricating microfluidic devices. This project aims to develop a novel 3D printer offering the highest resolution available and fastest printing speed for the single-step manufacturing of complex microfluidic devices. New resins developed to exploit the inert liquid interface layer printing approach will provide unprecedented capability to create micron sized channels interconnected in 3D space and fabricate Lab-on-a-Chip systems that cannot be generated by any current fabrication approach. This novel high speed, high fidelity 3D printer and the new resins to be developed are expected to lead to more effective manufacturing approaches for portable chemical devices and to promote complex chemical analysis into the knowledge immediacy culture of today.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100094
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Development of a world-class facility for three dimensional dynamic testing. Development of a world-class facility for three dimensional dynamic testing: This project aims to establish a world-class facility for multi-directional dynamic testing. Currently there are no such facilities in Australia. The ability to recreate dynamic motion in all available degrees-of-freedom opens up enormous fields of research not currently possible in Australia. This includes such areas as vibration testing, mate ....Development of a world-class facility for three dimensional dynamic testing. Development of a world-class facility for three dimensional dynamic testing: This project aims to establish a world-class facility for multi-directional dynamic testing. Currently there are no such facilities in Australia. The ability to recreate dynamic motion in all available degrees-of-freedom opens up enormous fields of research not currently possible in Australia. This includes such areas as vibration testing, materials testing, biomechanics and human factors, blast and earthquake simulations, field robotics, automotive safety research, flight/vehicle simulation, and marine applications including sloshing of liquids and liquefaction of fines. In conjunction with a 3D laser doppler system this facility will be unique in the world for dynamic mechanical testing.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100118
Funder
Australian Research Council
Funding Amount
$159,450.00
Summary
Sensor calibration facility for spectral and thermal remote sensing. This project aims to establish a calibration facility for the radiometric and spectral correction of hyperspectral and thermal sensors for ultrahigh-resolution remote sensing. Sensor calibration and characterisation is critical to the accuracy of hyperspectral and thermal data products, however, there is no central facility in Australia for this purpose. This project will provide significant benefits, such as growing our capaci ....Sensor calibration facility for spectral and thermal remote sensing. This project aims to establish a calibration facility for the radiometric and spectral correction of hyperspectral and thermal sensors for ultrahigh-resolution remote sensing. Sensor calibration and characterisation is critical to the accuracy of hyperspectral and thermal data products, however, there is no central facility in Australia for this purpose. This project will provide significant benefits, such as growing our capacity in ultrahigh-resolution remote sensing for ecosystem science, biosecurity, and disaster response.Read moreRead less
ARC Centre of Excellence for Electromaterials Science. The ARC Centre of Excellence for Electromaterials Science (ACES) will create next generation electrochemical devices via the precision assembly of nano/micro dimensional components into macroscopic structures. Through the discovery of new materials and structures, and understanding how spatial arrangement in 3D influences chemical, physical and biological properties, ACES will define the cutting edge of Electromaterials Science. The resultin ....ARC Centre of Excellence for Electromaterials Science. The ARC Centre of Excellence for Electromaterials Science (ACES) will create next generation electrochemical devices via the precision assembly of nano/micro dimensional components into macroscopic structures. Through the discovery of new materials and structures, and understanding how spatial arrangement in 3D influences chemical, physical and biological properties, ACES will define the cutting edge of Electromaterials Science. The resulting technology breakthroughs will have a direct impact on some of today's most challenging global problems in clean energy, synthetic biosystems, diagnostics and soft robotics. National benefit to Australia will be realised through the creation of new manufacturing industries.Read moreRead less
Special Research Initiatives - Grant ID: SR120200004
Funder
Australian Research Council
Funding Amount
$30,000,000.00
Summary
Australian Synchrotron Access Program. The Australian Synchrotron epitomises scientific research excellence in Australian and New Zealand. Its impact spans nearly every research sector. This proposal brings together over 30 Australian universities working together to ensure that world-class peer-reviewed science continues to be performed at the Australian Synchrotron.
Selectivity enhancement in separation science using responsive materials. Increasing public demand for quality products from the chemical, pharmaceutical, biotechnology and food industries requires access to innovative methods of chemical analysis. This project will establish a new class of separation materials of enhanced selectivity and resolving power for the fast, sensitive and reliable analysis of these products.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100009
Funder
Australian Research Council
Funding Amount
$620,000.00
Summary
Magnetometry Facility for Molecular and Nanoscale Materials. Advances in information and communications technology are critically dependent on increasing the capacity, speed and energy efficiency of logic and memory electronic devices. These improvements can be achieved by reducing component size to the nanoscale and using magnetic spin as well as charge. This Project aims to establish Australia's first integrated Magnetometry Facility for determining the magnetic properties of a range of nanosc ....Magnetometry Facility for Molecular and Nanoscale Materials. Advances in information and communications technology are critically dependent on increasing the capacity, speed and energy efficiency of logic and memory electronic devices. These improvements can be achieved by reducing component size to the nanoscale and using magnetic spin as well as charge. This Project aims to establish Australia's first integrated Magnetometry Facility for determining the magnetic properties of a range of nanoscale materials down to the level of individual nanomagnets. The Facility will provide crucial characterisation capabilities for Australian researchers, building capacity to develop new magnetic nanomaterials and devices for high-density data storage, quantum computing and spintronics.
Read moreRead less
Microfluidic technology to help understand physical damage to brain cells. Understanding the organisation, structure and mechanisms of the human brain and nervous system remains one of the biggest challenges of science. This project aims to develop a new cell culture platform to form defined molecular networks of brain cells and to monitor changes throughout the network in response to a small localised injury within the network. This innovative platform will be used to help understand changes wi ....Microfluidic technology to help understand physical damage to brain cells. Understanding the organisation, structure and mechanisms of the human brain and nervous system remains one of the biggest challenges of science. This project aims to develop a new cell culture platform to form defined molecular networks of brain cells and to monitor changes throughout the network in response to a small localised injury within the network. This innovative platform will be used to help understand changes within cells in response to physical damage to networks of brain cells. This is one of the major causes of death and disability in developed nations, and is identified as a risk factor for a range of neurodegenerative diseases including Alzheimer's, Parkinson's and motor neuron disease.Read moreRead less
Advanced matrix-analytic methods with applications. Over the last twenty-five years, matrix-analytic methods have proved to be very successful in formulating and analysing certain classes of stochastic models. Motivated by applications, this project will investigate more advanced matrix-analytic methods than have hitherto been studied.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100043
Funder
Australian Research Council
Funding Amount
$389,000.00
Summary
Rapid Molecular (Bio)material Imaging by Infrared and Raman Microscopies. This project aims to undertake fast probe-free biochemical/chemical imaging of heterogeneity within cells and materials surfaces with new infrared and Raman imaging. It will generate new fundamental knowledge on: cell heterogeneity and dynamic processes; technologies for optimising cell printing; understanding toxicity of microplastics; and protocols for measuring materials of technological relevance. Expected outcomes inc ....Rapid Molecular (Bio)material Imaging by Infrared and Raman Microscopies. This project aims to undertake fast probe-free biochemical/chemical imaging of heterogeneity within cells and materials surfaces with new infrared and Raman imaging. It will generate new fundamental knowledge on: cell heterogeneity and dynamic processes; technologies for optimising cell printing; understanding toxicity of microplastics; and protocols for measuring materials of technological relevance. Expected outcomes include: interdisciplinary collaborations in new protocols for in-vitro drug development; cell printing technologies; environmental impacts of microplastics; and materials design. Expected benefits include innovative approaches to early stage drug design; improved environmental controls and advances in innovative materials.Read moreRead less