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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100010
Funder
Australian Research Council
Funding Amount
$928,291.00
Summary
Single-molecule Manipulation and Interaction Facility (SMIF). This LIEF project aims to establish Australia's first Single-molecule Manipulation and Interaction Facility (SMIF), providing multidisciplinary researchers with a platform to explore cellular processes and reveal molecular mechanisms at the nanoscale. The SMIF facility incorporates cutting-edge technologies for bio-manipulation, real-time visualisation, and characterisation of single-molecule interactions, overcoming the technical com ....Single-molecule Manipulation and Interaction Facility (SMIF). This LIEF project aims to establish Australia's first Single-molecule Manipulation and Interaction Facility (SMIF), providing multidisciplinary researchers with a platform to explore cellular processes and reveal molecular mechanisms at the nanoscale. The SMIF facility incorporates cutting-edge technologies for bio-manipulation, real-time visualisation, and characterisation of single-molecule interactions, overcoming the technical complexity of traditional tools requiring highly specialised personnel. By offering accessible, easy-to-use advanced systems, this project will significantly boost scientific discovery across physics, chemistry, and biology, fostering collaboration and innovation to better understand life at the molecular level.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100964
Funder
Australian Research Council
Funding Amount
$456,354.00
Summary
Precision Rulers for the Visible - Chip Scale Optical Frequency Combs. This project aims to create a photonic chip technology that generates hundreds of coherent laser lines in the visible spectrum from a single chip for accurate sensing, imaging unknown objects and measuring gas emissions. The project expects to introduce this new capability in the current photonic chip technology, which currently only operates with infrared light. The expected outcomes are inexpensive, stable and energy-effici ....Precision Rulers for the Visible - Chip Scale Optical Frequency Combs. This project aims to create a photonic chip technology that generates hundreds of coherent laser lines in the visible spectrum from a single chip for accurate sensing, imaging unknown objects and measuring gas emissions. The project expects to introduce this new capability in the current photonic chip technology, which currently only operates with infrared light. The expected outcomes are inexpensive, stable and energy-efficient devices the size of a fingernail that will enable measurements with unprecedented accuracies. This should allow these devices to be mounted on drones, satellites, and robots, making them attractive for defence, information security, imaging, autonomous vehicle, and sensing applications.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100229
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
A prototype Scanning Helium Atom Microscope (SHeM) for soft materials. The scanning helium atom microscope (SHeM) has been a tantalising prospect since the birth of quantum physics. The SHeM would have unparalleled resolution and would be completely non-damaging; potentially revolutionising the imaging of soft delicate materials. This project will develop the first SHeM instrument in Australia to study soft matter.
Phonon based condensed matter imaging. This project will exploit observations of phonon-based chemical contrast in the SHeM to determine the physics that underpins the imaging mechanism and use them to probe vibrational processes in condensed matter imaging. Imaging is an essential tool for the discovery, application and fabrication of new materials, structures and devices. However, many delicate structures are irrevocably degraded and changed when imaged using conventional microscopy. This team ....Phonon based condensed matter imaging. This project will exploit observations of phonon-based chemical contrast in the SHeM to determine the physics that underpins the imaging mechanism and use them to probe vibrational processes in condensed matter imaging. Imaging is an essential tool for the discovery, application and fabrication of new materials, structures and devices. However, many delicate structures are irrevocably degraded and changed when imaged using conventional microscopy. This team recently invented the scanning helium atom microscope (SHeM), which can image surfaces non-destructively with nanoscale resolution. They will use the SHeM to determine the new fundamental physics that underpins the imaging mechanism. Outcomes include turning SHeM into a tool that materials and biological scientists can use in laboratories worldwide.Read moreRead less
Acoustic single cell traps: Understanding the woods by examining the trees. This project aims to define the underlying physics behind the manipulation of individual cells in a microfluidic chip using acoustic forces. The technology investigated would offer biomedical researchers a unique capability: that of tracking individual cell responses. It is known for example that drug resistance and latency emerge from small sub-populations of cells, so crucial information is lost when cells are studied ....Acoustic single cell traps: Understanding the woods by examining the trees. This project aims to define the underlying physics behind the manipulation of individual cells in a microfluidic chip using acoustic forces. The technology investigated would offer biomedical researchers a unique capability: that of tracking individual cell responses. It is known for example that drug resistance and latency emerge from small sub-populations of cells, so crucial information is lost when cells are studied at a population level. To trap single cells, the acoustic wavelength excited must be reduced to the order of a cell diameter. By enabling the analysis of different responses due to subtle cell difference, information pertinent to infection pathways and drug response could be gathered.Read moreRead less
3D integrated crystalline UV optical lens-fiber couplers for astronomy. This project aims to create micro-optics for astronomical and bio medical applications by 3D sculpturing them out of crystals by ultra-short pulse lasers. This project will introduce a new 3D fabrication approach of optical probes which have self-aligned micro-optical elements and optical fibres for a wide spectral range and with high quality optical surfaces. Expected outcomes of this project include building new capabiliti ....3D integrated crystalline UV optical lens-fiber couplers for astronomy. This project aims to create micro-optics for astronomical and bio medical applications by 3D sculpturing them out of crystals by ultra-short pulse lasers. This project will introduce a new 3D fabrication approach of optical probes which have self-aligned micro-optical elements and optical fibres for a wide spectral range and with high quality optical surfaces. Expected outcomes of this project include building new capabilities in micro-optical probes for industrial environments, establishing new solutions for international astronomy partners, and developing new techniques to image through optical fibres. This should provide significant benefits by improving astronomical instrumentation and also lead to less invasive endoscopy.Read moreRead less
Integration of DNA switches into wearables for smart chemical monitoring. This project addresses the scientific challenge of real-time monitoring of dynamic biological changes in the secretions found in sweat. By creating a wearable wireless device to monitor chemicals which interests Nutromics, using a novel electronic skin technology platform, the work aims to generate new knowledge of physiological changes in sweat secretions. Lying at the interface of analytical chemistry, functional materia ....Integration of DNA switches into wearables for smart chemical monitoring. This project addresses the scientific challenge of real-time monitoring of dynamic biological changes in the secretions found in sweat. By creating a wearable wireless device to monitor chemicals which interests Nutromics, using a novel electronic skin technology platform, the work aims to generate new knowledge of physiological changes in sweat secretions. Lying at the interface of analytical chemistry, functional materials and biomedical engineering, the project will contribute to the training of young researchers in these emerging technologies which interest Nutromics Pty Ltd. The project will improve Australia's standing in technology around wearable devices, improving our global competitive edge with economic and scientific impact.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100124
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Rapid prototyping 3-D nano-pattern large area writer . Rapid prototyping 3-D nano-pattern large area writer:
The project aims to establish a nanoscale three-dimensional patterning rapid prototyping capability to enable advanced nanofabrication research and development. The extension of patterning nanostructured materials in three dimensions with nanometre resolution, developed for semiconductor processing, to nano-electronics, nanophotonics, nanosensors, nanobiotechnology and fundamental studi ....Rapid prototyping 3-D nano-pattern large area writer . Rapid prototyping 3-D nano-pattern large area writer:
The project aims to establish a nanoscale three-dimensional patterning rapid prototyping capability to enable advanced nanofabrication research and development. The extension of patterning nanostructured materials in three dimensions with nanometre resolution, developed for semiconductor processing, to nano-electronics, nanophotonics, nanosensors, nanobiotechnology and fundamental studies of nanoscale phenomena in science and engineering has opened new opportunities in these areas. As these areas accelerate, there is a need to develop nanoscale patterns and structures via rapid prototyping pathways and with methods accessible to an ever-diverse researcher base without a background in nanofabrication. By establishing the first NanoFrazor in Australia, this project aims to provide new technology for the fabrication of high-resolution nanoscale structures and patterns.
Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100233
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Characterisation of infrared imaging technologies. This project aims to establish a facility for two-dimensional (2D) infrared sensor array testing and prototyping. Systematic characterisation and prototyping of 2D imaging arrays is vital in showcasing and realising Australia's innovation and research investment in photodetector technologies. This facility will enable research on 2D imaging arrays, such as pixel yield and cross-talk, device reliability physics, failure mechanisms, noise and long ....Characterisation of infrared imaging technologies. This project aims to establish a facility for two-dimensional (2D) infrared sensor array testing and prototyping. Systematic characterisation and prototyping of 2D imaging arrays is vital in showcasing and realising Australia's innovation and research investment in photodetector technologies. This facility will enable research on 2D imaging arrays, such as pixel yield and cross-talk, device reliability physics, failure mechanisms, noise and long-term stability. The facility will demonstrate Australia's innovative imaging technologies, applicable in science, industry, defence and security, attracting interest from both Australian and international industries.Read moreRead less
Dielectric contrast imaging for 7 Tesla magnetic resonance applications. This project aims to develop novel radio-frequency (RF) technology, ensuring that the benefits of high-field magnetic resonance imaging (MRI) are available for a broader range of applications. This project will develop a new contrast mechanism directly related to the RF properties of individual tissue types, circumventing a limitation of intensity based imaging. This technology will enhance Australia’s global impact the dev ....Dielectric contrast imaging for 7 Tesla magnetic resonance applications. This project aims to develop novel radio-frequency (RF) technology, ensuring that the benefits of high-field magnetic resonance imaging (MRI) are available for a broader range of applications. This project will develop a new contrast mechanism directly related to the RF properties of individual tissue types, circumventing a limitation of intensity based imaging. This technology will enhance Australia’s global impact the development of imaging technology for healthcare, biomedical research and advanced diagnostics.Read moreRead less