Discovery Early Career Researcher Award - Grant ID: DE200100279
Funder
Australian Research Council
Funding Amount
$424,198.00
Summary
A nanodiamond voltage sensor: towards real-time, long-term neuronal sensing. This project aims to develop a voltage sensor that may ultimately be used to measure neuronal signals noninvasively in real-time and over hours. The project expects to generate the fundamental science needed to use nanodiamonds for fluorescence-based voltage sensing that can be easily measured using optical microscopy. The expected outcome is a biocompatible sensor that should provide a solution to one of the biggest ch ....A nanodiamond voltage sensor: towards real-time, long-term neuronal sensing. This project aims to develop a voltage sensor that may ultimately be used to measure neuronal signals noninvasively in real-time and over hours. The project expects to generate the fundamental science needed to use nanodiamonds for fluorescence-based voltage sensing that can be easily measured using optical microscopy. The expected outcome is a biocompatible sensor that should provide a solution to one of the biggest challenges in neuroscience; the fast, precise and long-term measurement of neuronal activity. This technology may one day inform our understanding of how the normal brain works and provide major insights into mental health conditions and neurodegenerative diseases.Read moreRead less
A new generation flat screen: metasurface displays. This project aims to develop a new generation flat screen that is lighter, more efficient and with higher resolution by replacing the traditional liquid crystals (LCs) with metasurfaces that are 100-times thinner than LCs. Metasurfaces are arrays of engineered dielectric and semiconductor nanoparticles, with extraordinary characteristics. The expected outcomes will lead to flat screens with resolution enhanced by 100 times and energy consumptio ....A new generation flat screen: metasurface displays. This project aims to develop a new generation flat screen that is lighter, more efficient and with higher resolution by replacing the traditional liquid crystals (LCs) with metasurfaces that are 100-times thinner than LCs. Metasurfaces are arrays of engineered dielectric and semiconductor nanoparticles, with extraordinary characteristics. The expected outcomes will lead to flat screens with resolution enhanced by 100 times and energy consumption reduced by half, as compared to current LC-based displays (e.g. LCD and LED). This novel technology will revolutionise the dimension and performance of displays and secure Australia's position in the billion dollar market of flat displays.
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High-brightness, low-efficiency roll-off materials for augmented realities. The proposal aims to apply new materials design theory to create new classes of highly efficient materials and overcome device efficiency roll-off issue for next-generation transparent electronics. The project expects to advance new see-through technology through new materials and device architectures innovations. Expected key outcomes include novel highly efficient multi-nuclear metal complexes generation, establishment ....High-brightness, low-efficiency roll-off materials for augmented realities. The proposal aims to apply new materials design theory to create new classes of highly efficient materials and overcome device efficiency roll-off issue for next-generation transparent electronics. The project expects to advance new see-through technology through new materials and device architectures innovations. Expected key outcomes include novel highly efficient multi-nuclear metal complexes generation, establishment of new knowledge of materials’ structure-property relationship and fundamental understanding of device physics, creation of new transparent display pixels, new training of young scientists and new IPs generation, which will provide benefits to maximise Australia's competitive advantages and meet with global innovation need.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101156
Funder
Australian Research Council
Funding Amount
$426,476.00
Summary
Preconcentrators for vapour detection of explosive material. This Project’s aim is to develop a preconcentrator technology for the in-field detection of explosive vapours that have low concentrations in air. Low explosive vapour concentration limits the efficacy of portable detectors. Current preconcentrator technologies sorb vapours but require heat to release the concentrated material limiting their use to non-portable detectors. This project is expected to deliver materials and a device modul ....Preconcentrators for vapour detection of explosive material. This Project’s aim is to develop a preconcentrator technology for the in-field detection of explosive vapours that have low concentrations in air. Low explosive vapour concentration limits the efficacy of portable detectors. Current preconcentrator technologies sorb vapours but require heat to release the concentrated material limiting their use to non-portable detectors. This project is expected to deliver materials and a device module for a preconcentrator technology that will sorb explosive analytes, have low power requirements and be compatible with hand held explosives detectors. Security and law enforcement agencies should directly benefit from these findings, which would advance their safety and that of the community as a whole.Read moreRead less
Energy resolving photodetection through extracting hot carrier photocurrent. The project will develop infrared metallic hot-electron photodetectors for energy and wavelength resolving photodetection. With the varied applications of infrared photodetectors in Australia, the project aims to establish a novel photodiode architecture that harnesses thermal energy through hot-electrons for high speed and broadband photodetection. By enabling energy resolving photodetection, the photodiode will combi ....Energy resolving photodetection through extracting hot carrier photocurrent. The project will develop infrared metallic hot-electron photodetectors for energy and wavelength resolving photodetection. With the varied applications of infrared photodetectors in Australia, the project aims to establish a novel photodiode architecture that harnesses thermal energy through hot-electrons for high speed and broadband photodetection. By enabling energy resolving photodetection, the photodiode will combine research laboratory scale capabilities into a single optical element. Advanced hot-electron absorber materials will be studied. The research outcomes have applications from telecommunications to biotechnology where photodetectors are a critical sensing component, and for metallic hot electrons utilised in photocatalysis.Read moreRead less
ARC Centre of Excellence in Exciton Science. This Centre aims to manipulate the way light energy is absorbed, transported and transformed in advanced molecular materials. The research programme spans high-throughput computational screening, single molecule photochemistry and ultrafast spectroscopy and embraces innovative outreach and commercial translation activities. The Centre plans to capture the knowledge generated as new intellectual property, materials processing know-how, and through the ....ARC Centre of Excellence in Exciton Science. This Centre aims to manipulate the way light energy is absorbed, transported and transformed in advanced molecular materials. The research programme spans high-throughput computational screening, single molecule photochemistry and ultrafast spectroscopy and embraces innovative outreach and commercial translation activities. The Centre plans to capture the knowledge generated as new intellectual property, materials processing know-how, and through the creation of new employment opportunities. The expected outcomes and benefits include new Australian technologies in solar energy conversion, energy-efficient lighting and displays, security labelling and optical sensor platforms for defence.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190101514
Funder
Australian Research Council
Funding Amount
$352,473.00
Summary
Nanodroplet platforms for engineering novel nanocarbon structures. This project aims to exploit surface nanodroplet array platforms to construct multi-scale level assembly of nanometer-scale carbon materials. The project expects to advance knowledge on the interactions between droplets and carbon nanomaterials to enable controlled construction of nanocarbon based optoelectric devices. Successful adoption of nanocarbon material-based optoelectronic devices by the energy conversion industry has th ....Nanodroplet platforms for engineering novel nanocarbon structures. This project aims to exploit surface nanodroplet array platforms to construct multi-scale level assembly of nanometer-scale carbon materials. The project expects to advance knowledge on the interactions between droplets and carbon nanomaterials to enable controlled construction of nanocarbon based optoelectric devices. Successful adoption of nanocarbon material-based optoelectronic devices by the energy conversion industry has the potential to increase efficiency of conversion and reduce the cost of manufacture. The expected outcomes are large scale and well-ordered nanocarbon structures with excellent electronic and optical properties.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100550
Funder
Australian Research Council
Funding Amount
$458,127.00
Summary
Superior performance optical coatings for next-generation interferometry. This project aims to investigate fundamental noise in optical coatings, a limiting factor for state-of-the-art astronomical observatories, global timing standards, and photonics applications. Gravitational wave detectors, marvels of precision engineering that have produced ground-breaking discoveries in fundamental science, are particularly afflicted by coating noise. The proposed experiment plans to operate at cryogenic t ....Superior performance optical coatings for next-generation interferometry. This project aims to investigate fundamental noise in optical coatings, a limiting factor for state-of-the-art astronomical observatories, global timing standards, and photonics applications. Gravitational wave detectors, marvels of precision engineering that have produced ground-breaking discoveries in fundamental science, are particularly afflicted by coating noise. The proposed experiment plans to operate at cryogenic temperatures with unprecedented sensitivity to conduct feasibility studies of deposition methods, coating materials, and layer structures. The goal is to deploy innovative methods to develop Australian-made optical coatings with superior performance and merit for the most demanding scientific and industrial applications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100985
Funder
Australian Research Council
Funding Amount
$427,116.00
Summary
Shining a Light on Brain Temperature with Near-Infrared Nanosensors. This project aims to develop a contactless thermometry approach based on near-infrared fluorescence to map brain or nerve temperature in real-time. This research expects to generate new knowledge in the field of neuroscience using tools from optics, nanotechnology and materials science. The technique generated as a result of this project is expected to enable the quantification of the transient local heating of the nervous syst ....Shining a Light on Brain Temperature with Near-Infrared Nanosensors. This project aims to develop a contactless thermometry approach based on near-infrared fluorescence to map brain or nerve temperature in real-time. This research expects to generate new knowledge in the field of neuroscience using tools from optics, nanotechnology and materials science. The technique generated as a result of this project is expected to enable the quantification of the transient local heating of the nervous system in different situations and the study of how this affects neural function. This is expected to provide significant benefits, enabling the development of regulatory frameworks that ensure the safe implementation of new therapies for neurological and neurodegenerative disorders.Read moreRead less
Optimising catalyst performance by tuning adsorption with light. This project aims to utilize visible light to control reactant adsorption on catalyst surfaces for accelerating reactions and tuning product selectivity. Visible light irradiation of plasmonic metal nanoparticles can generate a force that attracts reactant to the nanoparticles in a catalyst, and causes desorption of other reactant-types from the particles. These compound-selective effects can alter the concentrations of reactants a ....Optimising catalyst performance by tuning adsorption with light. This project aims to utilize visible light to control reactant adsorption on catalyst surfaces for accelerating reactions and tuning product selectivity. Visible light irradiation of plasmonic metal nanoparticles can generate a force that attracts reactant to the nanoparticles in a catalyst, and causes desorption of other reactant-types from the particles. These compound-selective effects can alter the concentrations of reactants at the catalyst surface, a new paradigm for optimising catalytic performance. This project expects to open new capabilities within fields of catalysis and light-matter interaction. The anticipated outcomes include significant advancement of knowledge in catalysis and new approaches for important chemical synthesis.Read moreRead less