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Micro-electromechanical technology for harnessing terahertz waves. This project proposes novel low-cost miniature devices for spectral, spatial and temporal manipulation of terahertz waves realised using a unified platform based on a single material and fabrication technology sufficiently generic to span the entire very broad terahertz band. It inherently overcomes the most hindering issue of current terahertz instruments relating to the limited span of the spectrum each tool can cover and the h ....Micro-electromechanical technology for harnessing terahertz waves. This project proposes novel low-cost miniature devices for spectral, spatial and temporal manipulation of terahertz waves realised using a unified platform based on a single material and fabrication technology sufficiently generic to span the entire very broad terahertz band. It inherently overcomes the most hindering issue of current terahertz instruments relating to the limited span of the spectrum each tool can cover and the high costs associated with increasing this span; removing the need for making spectral band compromises in the design of future tools. The intended outcome is a platform for terahertz spectroscopic imaging, target recognition, detection of chemical composition of objects, and future high-bandwidth communications.Read moreRead less
Parallel Lines: Ultra-dense optical systems for extreme data-rates. The project aims to explore methods to significantly expand global internet data rates, by using emerging ultra-dense optical technologies. The project plans to discover how novel existing and emerging tiny photonic chip devices may enable the use of new, unused optical spectral bands, and then enable 1000s of channels to be supported by exploiting newly available parallelism in both wavelength and space. Success in the project ....Parallel Lines: Ultra-dense optical systems for extreme data-rates. The project aims to explore methods to significantly expand global internet data rates, by using emerging ultra-dense optical technologies. The project plans to discover how novel existing and emerging tiny photonic chip devices may enable the use of new, unused optical spectral bands, and then enable 1000s of channels to be supported by exploiting newly available parallelism in both wavelength and space. Success in the project aims may enable speeds of up to 100 times greater than achievable today, in a variety of fibre optic systems. Connectivity is key to our society, so benefits may arise in both future-proofing key Australian data infrastructure, and in providing a roadmap to support exponential capacity growth over the coming decades.Read moreRead less
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
Highly Efficient Solar Window Technology Enabled by Quantum Dots. The transition to zero-greenhouse gas emitting buildings is hindered by the lack of efficient energy generating building components with good aesthetics. This project will develop integrated solar windows that can effectively convert the facades of urban buildings into energy generation sites, enabled by our nanomaterials having outstanding light emission efficiencies of over 90%, accompanied by our advanced light guiding strategi ....Highly Efficient Solar Window Technology Enabled by Quantum Dots. The transition to zero-greenhouse gas emitting buildings is hindered by the lack of efficient energy generating building components with good aesthetics. This project will develop integrated solar windows that can effectively convert the facades of urban buildings into energy generation sites, enabled by our nanomaterials having outstanding light emission efficiencies of over 90%, accompanied by our advanced light guiding strategies and innovative PV cell integration. This next generation technology can reduce the electricity cost and increase renewable energy adoption, placing Australia in a competitive position in the billion-dollar building integrated photovoltaic market whilst also contributing to decarbonising electricity generation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101711
Funder
Australian Research Council
Funding Amount
$452,154.00
Summary
Printed Infrared Quantum Dot Photodetectors and Large-scale Image Sensors . Detectors operating in shortwave infrared region are critical in civil and military applications. This project aims to demonstrate revolutionary low-cost and high performing shorwave infrared lead sulfide quantum dot photodetectors and large-scale image sensors with compatible structures for the potential applications on complementary metal–oxide–semiconductor readout integrated circuits through fully printing. Expected ....Printed Infrared Quantum Dot Photodetectors and Large-scale Image Sensors . Detectors operating in shortwave infrared region are critical in civil and military applications. This project aims to demonstrate revolutionary low-cost and high performing shorwave infrared lead sulfide quantum dot photodetectors and large-scale image sensors with compatible structures for the potential applications on complementary metal–oxide–semiconductor readout integrated circuits through fully printing. Expected outcomes of this project included the new understandings of surface passivation, interfacial engineering and device design. The shortwave technologies developed in this project will be highly prospective for commercialization in the near future, which would bring Australia’s shortwave technologies to a new stage. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100382
Funder
Australian Research Council
Funding Amount
$449,154.00
Summary
Charge and Energy Transfer Processes at Inorganic-Organic Interfaces . The integration of functional molecular materials with inorganic systems remains an outstanding hurdle to achieve durable, highly efficient optoelectronic devices. This project aims to develop and understand this new class of devices, with a focus on directional energy transfer processes across hybrid interfaces. This project expects to generate new knowledge in photovoltaics (PV) and for organic light emitting diodes (OLEDs) ....Charge and Energy Transfer Processes at Inorganic-Organic Interfaces . The integration of functional molecular materials with inorganic systems remains an outstanding hurdle to achieve durable, highly efficient optoelectronic devices. This project aims to develop and understand this new class of devices, with a focus on directional energy transfer processes across hybrid interfaces. This project expects to generate new knowledge in photovoltaics (PV) and for organic light emitting diodes (OLEDs) by studying triplet transfer in two model systems. The first will be a step towards the development of advanced PV devices using down-conversion to push solar cells beyond the efficiency barrier. The second will demonstrate inorganic-organic solid state up-conversion for next generation OLEDs with improved stability.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100587
Funder
Australian Research Council
Funding Amount
$443,347.00
Summary
A quantum telescope for extremely high-resolution imaging. This project will combine world-leading Australian signal stabilisation technology with recent developments in quantum sensors to demonstrate the world’s first quantum telescope. This project expects to demonstrate that quantum detectors can feasibly link optical telescopes, separated by hundreds of kilometres, to achieve extremely high-resolution imaging. Expected outcomes are the development of technologies that will enable imaging wit ....A quantum telescope for extremely high-resolution imaging. This project will combine world-leading Australian signal stabilisation technology with recent developments in quantum sensors to demonstrate the world’s first quantum telescope. This project expects to demonstrate that quantum detectors can feasibly link optical telescopes, separated by hundreds of kilometres, to achieve extremely high-resolution imaging. Expected outcomes are the development of technologies that will enable imaging with resolution more than 20 times better than any existing telescope. This will provide significant benefits for astronomy, space situational awareness, and defence.Read moreRead less