Smart passive sampling of heavy metals in aquatic systems. Smart passive sampling of heavy metals in aquatic systems. This project aims to construct smart devices with extracting polymeric membranes for advanced passive sampling of heavy metal ions. These devices should improve the passive sampling of pollutants such as heavy metals by overcoming the effect of the variability of water temperature, composition and velocity during sampling, which substantially reduces the reliability of analytical ....Smart passive sampling of heavy metals in aquatic systems. Smart passive sampling of heavy metals in aquatic systems. This project aims to construct smart devices with extracting polymeric membranes for advanced passive sampling of heavy metal ions. These devices should improve the passive sampling of pollutants such as heavy metals by overcoming the effect of the variability of water temperature, composition and velocity during sampling, which substantially reduces the reliability of analytical data. These devices are expected to reliably identify sources of heavy metal pollution in urban municipal wastewaters and stormwaters without the need for labour intensive monitoring operations, thus saving considerable time and expense to the Australian water industry.Read moreRead less
Spatial sound control for testing multi-channel audio devices. Spatial sound control for testing multi-channel audio devices. This project aims to test Alternative Listening Devices/Personal Sound Amplification Devices (PSAPs), multi-input audio devices fast replacing hearing aids due to their affordability and easy accessibility. With more consumers choosing PSAPs, proper testing is needed to assess the devices’ safety and benefit in real-life acoustic situations. This project will test PSAPs i ....Spatial sound control for testing multi-channel audio devices. Spatial sound control for testing multi-channel audio devices. This project aims to test Alternative Listening Devices/Personal Sound Amplification Devices (PSAPs), multi-input audio devices fast replacing hearing aids due to their affordability and easy accessibility. With more consumers choosing PSAPs, proper testing is needed to assess the devices’ safety and benefit in real-life acoustic situations. This project will test PSAPs in laboratory setups that use spatial audio processing techniques to mimic realistic acoustic environments, and develop theoretical frameworks to overcome existing limitations to accurate spatial sound reproduction. This research is expected to provide innovative solutions to safeguard Australia's future hearing health.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101046
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Ecotoxicology-on-a-chip: towards smart devices in environmental biomonitoring. High-throughput water quality monitoring is of great importance to the wellbeing of Australian society. The project will address this issue by developing new economical miniaturised biocybernetic instrumentation, designed for use by non-specialists and thus applicable for governmental, industrial and community projects.
Development of novel passive sampling devices for ammonia monitoring. This project will develop novel inexpensive passive samplers for ammonia which is an indicator for faecal contamination in stormwater. These devices will increase dramatically the efficiency in isolating intermittent faecal contamination sources in drainage networks by eliminating the need for extensive manual sampling and inspection operations.
Advanced Signal Processing for Radiation Spectroscopy. Southern Innovation develops and markets world-leading pulse processing technologies for the rapid, accurate detection and measurement of radiation. The underlying real-time signal processing challenge relates to isolating often overlapping pulses, determining when each pulse arrived and the energy of each pulse. Recent advances in the computational power of digital signal processing boards makes it timely to develop innovative pulse process ....Advanced Signal Processing for Radiation Spectroscopy. Southern Innovation develops and markets world-leading pulse processing technologies for the rapid, accurate detection and measurement of radiation. The underlying real-time signal processing challenge relates to isolating often overlapping pulses, determining when each pulse arrived and the energy of each pulse. Recent advances in the computational power of digital signal processing boards makes it timely to develop innovative pulse processing algorithms based on optimal filtering of stochastic processes. It is expected that these algorithms will have widespread impact, both commercially for minerals exploration, materials analysis, medical imaging and security screening, and scientifically for improving the performance of synchrotrons and other equipment.Read moreRead less
Control, estimation and nanopositioning for high-throughput probe-storage. Probe-storage is a new technology for storing digital information as tiny indentations on a storage medium. It offers the highest data storage density compared with alternative technologies. This project aims to develop methods and the underpinning theory to realise a new probe-storage memory that is much faster and can store data at much higher rates.
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
Discovery Early Career Researcher Award - Grant ID: DE170100821
Funder
Australian Research Council
Funding Amount
$381,000.00
Summary
Hyper-domain luminescence lifetime imaging for mapping molecular dynamics. This project aims to enable lifetime-multiplexed optical imaging of molecular dynamics of biological systems in real time. The grand challenge of modern life sciences is to understand the molecular origins of complex processes. Using lifetime measurement, this project will realise highly-multiplexed real-time luminescence imaging with simultaneous ultrahigh detection sensitivity and spatial resolution. By generating fresh ....Hyper-domain luminescence lifetime imaging for mapping molecular dynamics. This project aims to enable lifetime-multiplexed optical imaging of molecular dynamics of biological systems in real time. The grand challenge of modern life sciences is to understand the molecular origins of complex processes. Using lifetime measurement, this project will realise highly-multiplexed real-time luminescence imaging with simultaneous ultrahigh detection sensitivity and spatial resolution. By generating fresh insights into molecular fingerprints of relevance for future disease diagnostics and treatment, the project outcomes are expected to consolidate Australia’s leading position in the health sciences. Upon commercialisation, the intellectual property is expected to generate considerable economic returns.Read moreRead less
Developing a simple method for characterising the mechanical properties of nanowhiskers. This project aims to accurately measure mechanical properties of nanostructures, addressing a challenging issue in the ongoing development of nanotechnology. The success of this project will provide important advances in the understanding of the mechanical behaviour of nanowhiskers and assist in the further development of nanomaterials.
Liquid crystal-based optical fibre hydrophone system for underwater surveillance and ocean monitoring. The aim of this project is to design, implement and optimise a new class of optical sensing system which targets underwater surveillance and ocean monitoring. This project is expected to lead to improved national security, broaden Australia's photonics knowledge base, and contribute to greater international scientific collaboration.