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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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Discovery Early Career Researcher Award - Grant ID: DE120101721
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Probing the excited states of organic semiconductor systems with photoinduced absorption spectroscopy. Plastic semiconductors have the potential to revolutionise consumer electronics by enabling cheap, flexible and low power devices. The success of these devices depends on our understanding of the optical and electronic properties of the materials, which this project aims to address through the use of photoinduced absorption spectroscopy.
Discovery Early Career Researcher Award - Grant ID: DE130101300
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Molecules and mirrors: new directions in chemistry and organic optoelectronics using hybrid light or matter states. This project will explore the exotic mixtures of light and matter that can form when molecules are placed in nano-scale mirror cavities. If the chemical reactivity of these mixed light or matter states can be controlled, a new generation of efficient, organic solar energy capture and storage devices is anticipated.
Enabling on-chip mid-infrared laser technology by overcoming parasitic loss in Group IV semiconductors. Miniaturised and on-chip mid-infrared lasers are needed in many fields, particularly defence, medicine and environmental sensing. This project will overcome problems in key semiconductor materials to create practical devices with the properties needed to address challenges of national security and commercial importance.
Beyond Spectral Detection: Engineering SUPER Dot Probes for High-Throughput Discovery. Molecules that are altered as a result of a pathological condition are generally present in very low abundance, and pose a “needle-in-a-haystack” problem. Current detection, quantification and localisation technologies use fluorescent probes that are limited by sensitivity and analysis time. This project will develop a new generation of nanophotonic luminescent probes (Strong Upconversion Photo-stable Encoded ....Beyond Spectral Detection: Engineering SUPER Dot Probes for High-Throughput Discovery. Molecules that are altered as a result of a pathological condition are generally present in very low abundance, and pose a “needle-in-a-haystack” problem. Current detection, quantification and localisation technologies use fluorescent probes that are limited by sensitivity and analysis time. This project will develop a new generation of nanophotonic luminescent probes (Strong Upconversion Photo-stable Encoded nano-Radiators (SUPER) Dots), based on purpose-engineered up-conversion nanocrystals that are ultra-bright and have low background interference, high specificity, speed, and large-scale multiplexing capacity. These probes will allow microscopy and flow cytometry to measure hitherto undetectable rare-event molecules and cells, opening new frontiers for the discovery of new biomarkers.Read moreRead less
Quantum dot-sensitised solar cells: can efficiency beyond the Shockley-Queisser limit be achieved? The project will address key barriers to broader commercialisation of cost-effective titania-based solar cells by utilising novel physics of semiconductor quantum dot materials used as a sensitiser. The research outcomes will answer key questions about the ultimate efficiency of these cells, and help transform the Australian PV industry.
Deep-ultraviolet light source by frequency doubling of blue or green light for disinfection. Current ultraviolet light sources are inefficient and often bulky. By an alternative approach, in which the wavelength of blue or green light is halved, this project will design and build compact, efficient sources of ultraviolet light, which can be used for disinfection and sterilization. Such devices can be fabricated by Australian industry in Australia.
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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100107
Funder
Australian Research Council
Funding Amount
$415,000.00
Summary
Time-resolved terahertz and optical spectroscopy facility. Time-resolved terahertz and optical spectroscopy facility:
This project aims to use time-resolved terahertz and optical spectroscopy as techniques to probe the photogenerated exciton and charge carrier dynamics at the heart of solar energy technologies. The dynamics of electrons and nuclei following the absorption of light involves processes which occur on timescales from femtoseconds to microseconds. The ability to probe these dynamics ....Time-resolved terahertz and optical spectroscopy facility. Time-resolved terahertz and optical spectroscopy facility:
This project aims to use time-resolved terahertz and optical spectroscopy as techniques to probe the photogenerated exciton and charge carrier dynamics at the heart of solar energy technologies. The dynamics of electrons and nuclei following the absorption of light involves processes which occur on timescales from femtoseconds to microseconds. The ability to probe these dynamics is of great importance for understanding the underlying photophysics and photochemistry of a range of technologies including solar photovoltaics and solar photocatalysis. This facility would enable researchers to deeply understand the photophysical processes occurring in advanced photovoltaic and photocatalysis materials and devices and may facilitate the development of advanced materials for renewable energy. Read moreRead less