Circuit-based monitoring and characterisation of high performance semiconductor processes. As a frontier technology, this project extends Australia's leadership in wireless communications. Potentially this project provides the key enabling method for integrated circuits to take full advantage of future generations of semiconductor technology. National Research Priorities safeguarding Australia and promoting and maintaining good health will also be impacted through more capable circuits for def ....Circuit-based monitoring and characterisation of high performance semiconductor processes. As a frontier technology, this project extends Australia's leadership in wireless communications. Potentially this project provides the key enabling method for integrated circuits to take full advantage of future generations of semiconductor technology. National Research Priorities safeguarding Australia and promoting and maintaining good health will also be impacted through more capable circuits for defence electronics and anti-terrorism, medical remote sensing and networking. The innovations here will make Sapphicon, Australia's only commercial integrated circuit manufacturer, more competitive and indirectly benefit National ICT Australia (NICTA), Commonwealth Scientific and Industrial Research Organisation (CSIRO), Defence Science and Technology Organisation (DSTO), the National Broadband Network and a host of other high-performance electronics concerns.Read moreRead less
Autonomous body sensors in humans: investigating new bio-sensing techniques with self-power generation. Using advanced integrated electronic and mechanical systems, it is now possible to design small biomedical sensors that can be inserted into the body to take biological measurements. This project introduces a new kind of bio-sensors with self-energy generation capability and reduces the need for periodic battery replacement. New wireless and circuit techniques are investigated to reduce power ....Autonomous body sensors in humans: investigating new bio-sensing techniques with self-power generation. Using advanced integrated electronic and mechanical systems, it is now possible to design small biomedical sensors that can be inserted into the body to take biological measurements. This project introduces a new kind of bio-sensors with self-energy generation capability and reduces the need for periodic battery replacement. New wireless and circuit techniques are investigated to reduce power consumption and physical dimensions, while providing a better performance and a safer wireless link. The project aims to deliver high level of comfort, better mobility and better patient care.Read moreRead less
Substrate-integrated wearable antennas for unobtrusive activity monitoring. This project aims to develop a novel class of wearable textile antennas that can form robust connections with miniature battery-less motion sensors for non-invasive activity monitoring of older people. In contrast to bulky body worn sensors that must be strapped on, it is anticipated that the garment-integrated textile antennas patterned through computerised embroidery will lead to low-cost, low-profile, and flexible ant ....Substrate-integrated wearable antennas for unobtrusive activity monitoring. This project aims to develop a novel class of wearable textile antennas that can form robust connections with miniature battery-less motion sensors for non-invasive activity monitoring of older people. In contrast to bulky body worn sensors that must be strapped on, it is anticipated that the garment-integrated textile antennas patterned through computerised embroidery will lead to low-cost, low-profile, and flexible antennas that are truly wearable with exceptional performance and scalable manufacturing techniques. The outcomes from the project are expected to underpin innovative applications, such as aged care, providing a means for caregivers to automatically monitor health and physical activity and intervene as required. Such applications would support ageing Australians to live with greater independence and safety.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100159
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
National facility for biased target deposition of alloyed nanolayers. This facility will enhance Australia's strengths and capabilities in fabricating structures, with applications in multiple research fields including opto-magneto-electronics, next generation lithium ion batteries and energy nanogenerators. It will enhance Australia's research profile as a leader in nanotechnology.
Rapid point-of-care detection of genomic variations for personalised medicine. Selecting treatment based on a person’s genetic profile can improve drug safety and efficacy, but the application is hampered by the inconvenience, slow result turnaround and high cost of current lab-based tests. Full implementation of personalised medicine in clinical practice requires a point-of-care testing system. This project aims to overcome the challenges involved in developing such a system by validating novel ....Rapid point-of-care detection of genomic variations for personalised medicine. Selecting treatment based on a person’s genetic profile can improve drug safety and efficacy, but the application is hampered by the inconvenience, slow result turnaround and high cost of current lab-based tests. Full implementation of personalised medicine in clinical practice requires a point-of-care testing system. This project aims to overcome the challenges involved in developing such a system by validating novel rapid genotyping methods and developing ultrasensitive real-time DNA detection that will be integrated on a single chip platform to facilitate a small, low cost and reliable test device. The technology will be readily adaptable to areas where prompt access to genomic information is valuable, such as disease diagnosis and risk prediction.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100001
Funder
Australian Research Council
Funding Amount
$410,000.00
Summary
Collaborative advanced spectroscopy facility for materials and devices. Collaborative advanced spectroscopy facility for materials and devices: This project aims to enable advancements in electronics, photonics, biomedicine, and sensing through a collaborative, open access facility for advanced optical and chemical spectroscopy of thin films, materials, and devices. The intended capabilities include high-speed, precise and state-of-the-art spectroscopy tools which enable in situ characterisation ....Collaborative advanced spectroscopy facility for materials and devices. Collaborative advanced spectroscopy facility for materials and devices: This project aims to enable advancements in electronics, photonics, biomedicine, and sensing through a collaborative, open access facility for advanced optical and chemical spectroscopy of thin films, materials, and devices. The intended capabilities include high-speed, precise and state-of-the-art spectroscopy tools which enable in situ characterisation at sub-micron scales and cryogenic temperatures, under bio-simulated environments, down to single pixel resolution, with parallel imaging and spectroscopy, and of fluids and biomaterials. The instrumentation will include cryogenic sub-micron photoluminescence and micro-Raman spectroscopy, single pixel optical and dark field spectroscopy, continuous wave terahertz time-domain spectroscopy, wide wavelength microscopic spectroscopy, and temperature-jump kinetics spectroscopy. It is expected that these complementary instruments will accelerate research in materials and devices for plasmonics, nanoelectronics, biomedicine, biochemistry, security, and forensic science.Read moreRead less
Diamond glass: An all-carbon technology for neural networks and biosensing. This project aims to use plasma deposition to synthesise diamond glass with the highest purity and the most diamond-like character so that it meets the strict requirements for emerging device applications. The extreme properties of diamond glass arise from the diamond-like bonding of the majority of its atoms. This amorphous, wide bandgap semiconductor is also the hardest known glass. The maximum diamond-like content pos ....Diamond glass: An all-carbon technology for neural networks and biosensing. This project aims to use plasma deposition to synthesise diamond glass with the highest purity and the most diamond-like character so that it meets the strict requirements for emerging device applications. The extreme properties of diamond glass arise from the diamond-like bonding of the majority of its atoms. This amorphous, wide bandgap semiconductor is also the hardest known glass. The maximum diamond-like content possible in diamond glass coatings is unknown, so determining its ultimate performance is difficult. Expected applications include medical diagnostics, non-volatile memories and programmable chips.Read moreRead less
Dynamic terahertz superlenses for sub-wavelength sensing and imaging. We propose to develop a 'dynamic terahertz superlens' that will dramatically enhance the performance of existing T-ray imaging systems used for biosensing of cells, DNA and proteins. The science of the superlens is remarkable in that it enables image resolution shorter than the wavelength.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100128
Funder
Australian Research Council
Funding Amount
$670,000.00
Summary
Helium and neon ion microscope for sub nanometer imaging and fabrication. The project's proposed instrument would add a new desperately needed capability to Australia's high resolution microscopy centre and nano fabrication facility and enable a wide range of users to image, measure, build and design complex nanostructures at the atomic level and upwards.
A novel platform-technology for long-term subcutaneous neurophysiology. This project aims to develop a novel miniature device for subcutaneous and tetherless brain sensing. It addresses the lack of a device solution for brain-sensing that combines ultra-long-term reliable sensing capability and small dimensions for minimally-invasive procedures. We achieve this through our novel electrode architecture that significantly enhances the quality and reliability of recorded brain signals. We introduce ....A novel platform-technology for long-term subcutaneous neurophysiology. This project aims to develop a novel miniature device for subcutaneous and tetherless brain sensing. It addresses the lack of a device solution for brain-sensing that combines ultra-long-term reliable sensing capability and small dimensions for minimally-invasive procedures. We achieve this through our novel electrode architecture that significantly enhances the quality and reliability of recorded brain signals. We introduce a platform technology designed for subscalp anatomy with future use in various brain-machine interfacing applications relying on reliable, long-term and easy-to-implant systems. This project's device manufacturing, training, and intellectual property are expected to strengthen Australia's position in bioelectronics.Read moreRead less